CN106199936A - Zoom lens - Google Patents
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- CN106199936A CN106199936A CN201510489710.XA CN201510489710A CN106199936A CN 106199936 A CN106199936 A CN 106199936A CN 201510489710 A CN201510489710 A CN 201510489710A CN 106199936 A CN106199936 A CN 106199936A
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- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B15/00—Optical objectives with means for varying the magnification
- G02B15/14—Optical objectives with means for varying the magnification by axial movement of one or more lenses or groups of lenses relative to the image plane for continuously varying the equivalent focal length of the objective
- G02B15/16—Optical objectives with means for varying the magnification by axial movement of one or more lenses or groups of lenses relative to the image plane for continuously varying the equivalent focal length of the objective with interdependent non-linearly related movements between one lens or lens group, and another lens or lens group
- G02B15/177—Optical objectives with means for varying the magnification by axial movement of one or more lenses or groups of lenses relative to the image plane for continuously varying the equivalent focal length of the objective with interdependent non-linearly related movements between one lens or lens group, and another lens or lens group having a negative front lens or group of lenses
-
- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B13/00—Optical objectives specially designed for the purposes specified below
- G02B13/18—Optical objectives specially designed for the purposes specified below with lenses having one or more non-spherical faces, e.g. for reducing geometrical aberration
-
- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B15/00—Optical objectives with means for varying the magnification
- G02B15/14—Optical objectives with means for varying the magnification by axial movement of one or more lenses or groups of lenses relative to the image plane for continuously varying the equivalent focal length of the objective
- G02B15/143—Optical objectives with means for varying the magnification by axial movement of one or more lenses or groups of lenses relative to the image plane for continuously varying the equivalent focal length of the objective having three groups only
- G02B15/1435—Optical objectives with means for varying the magnification by axial movement of one or more lenses or groups of lenses relative to the image plane for continuously varying the equivalent focal length of the objective having three groups only the first group being negative
- G02B15/143507—Optical objectives with means for varying the magnification by axial movement of one or more lenses or groups of lenses relative to the image plane for continuously varying the equivalent focal length of the objective having three groups only the first group being negative arranged -++
-
- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B15/00—Optical objectives with means for varying the magnification
- G02B15/14—Optical objectives with means for varying the magnification by axial movement of one or more lenses or groups of lenses relative to the image plane for continuously varying the equivalent focal length of the objective
- G02B15/144—Optical objectives with means for varying the magnification by axial movement of one or more lenses or groups of lenses relative to the image plane for continuously varying the equivalent focal length of the objective having four groups only
- G02B15/1445—Optical objectives with means for varying the magnification by axial movement of one or more lenses or groups of lenses relative to the image plane for continuously varying the equivalent focal length of the objective having four groups only the first group being negative
- G02B15/144511—Optical objectives with means for varying the magnification by axial movement of one or more lenses or groups of lenses relative to the image plane for continuously varying the equivalent focal length of the objective having four groups only the first group being negative arranged -+-+
-
- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B15/00—Optical objectives with means for varying the magnification
- G02B15/14—Optical objectives with means for varying the magnification by axial movement of one or more lenses or groups of lenses relative to the image plane for continuously varying the equivalent focal length of the objective
- G02B15/16—Optical objectives with means for varying the magnification by axial movement of one or more lenses or groups of lenses relative to the image plane for continuously varying the equivalent focal length of the objective with interdependent non-linearly related movements between one lens or lens group, and another lens or lens group
- G02B15/20—Optical objectives with means for varying the magnification by axial movement of one or more lenses or groups of lenses relative to the image plane for continuously varying the equivalent focal length of the objective with interdependent non-linearly related movements between one lens or lens group, and another lens or lens group having an additional movable lens or lens group for varying the objective focal length
-
- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B27/00—Optical systems or apparatus not provided for by any of the groups G02B1/00 - G02B26/00, G02B30/00
- G02B27/0025—Optical systems or apparatus not provided for by any of the groups G02B1/00 - G02B26/00, G02B30/00 for optical correction, e.g. distorsion, aberration
- G02B27/0068—Optical systems or apparatus not provided for by any of the groups G02B1/00 - G02B26/00, G02B30/00 for optical correction, e.g. distorsion, aberration having means for controlling the degree of correction, e.g. using phase modulators, movable elements
-
- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B5/00—Optical elements other than lenses
- G02B5/005—Diaphragms
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- Physics & Mathematics (AREA)
- General Physics & Mathematics (AREA)
- Optics & Photonics (AREA)
- Nonlinear Science (AREA)
- Lenses (AREA)
Abstract
The present invention provides the zoom lens possessing high optical property that are a kind of small-sized and that can make corrections all aberrations well in whole zoom region.These zoom lens are configured to, and are configured with the 1st battery of lens (G with negative power from object side successively11), there is the 2nd battery of lens (G of positive light coke12), there is the 3rd battery of lens (G of positive light coke13), and carry out zoom by the change at the interval on the optical axis of each battery of lens.Particularly, the 2nd battery of lens (G12) be configured to, from object side, it is configured with plus lens (L successively121), for determining the opening diaphragm (STP) of bore of regulation, minus lens (L122), plus lens (L123).It addition, the 3rd battery of lens (G13) be configured to, from object side, it is configured with minus lens (L successively131), plus lens (L132), plus lens (L133).Further, by the condition of satisfied regulation, it is possible to realize zoom lens that are small-sized and that possess high optical property.
Description
Technical field
The present invention relates to be suitable to be equipped with the small-sized shooting of the solid-state imagers such as CCD, CMOS
The zoom lens of device.
Background technology
Single-lens reflex camera, digital still photographing unit, video camera, monitoring camera etc. be equipped with CCD,
The camera head of the solid-state imagers such as COMS is popularized rapidly.It is accompanied by this, it is proposed that taking in a large number
It is loaded with the zoom lens (example that the camera head of the solid-state imagers such as CCD, CMOS can use
As, with reference to patent documentation 1~3).
Citation
Patent documentation
Patent documentation 1: Japanese Unexamined Patent Publication 2012-22080 publication
Patent documentation 2: Japanese Unexamined Patent Publication 2012-168513 publication
Patent documentation 3: No. 4283553 publications of Japanese Patent No.
In recent years, the high pixel of solid-state imager, high-sensitivity develop, for imaging lens system also
Require high optical property.It addition, the miniaturization of camera head, thus it also is intended to imaging lens system
Small-sized, lightness.Further, in order in the various uses such as monitoring camera, onboard camera
Use, also require that and tackle from visible domain to the powerful zoom lens of the light in near-infrared territory.
Zoom lens described in patent documentation 1 and 2 are the zoom lens with following structure, i.e.
Type easy of the battery of lens with negative, positive, positive focal power it is configured with successively from object side
Lens group structure.But, in these zoom lens, the 1st battery of lens, the lens of the 3rd battery of lens
Piece number is few, it is difficult to all aberrations that suppression produces in each battery of lens, therefore cannot obtain good image.
The most powerful image of this problem just becomes the most notable.It addition, near infrared light, at telescope end
On the axle produced, chromatic aberration, multiplying power chromatic aberration become notable, and make corresponding near infrared light optical
Can significantly deteriorate such problem to exist.
It addition, in the zoom lens described in patent documentation 3, carried out under high magnification from can
See that area of light arrives the optical aberration correcting of the light in near-infrared territory.But, owing to the 1st battery of lens has positive light coke,
If heavy caliber ratioization to be realized, optical system entirety becomes big trend and exists, and makes heavy caliber ratio
Change and miniaturization is taken into account difficult such problem and existed.
Summary of the invention
The problem that invention is to be solved
In order to eliminate the problem points of above-mentioned conventional art, it is an object of the invention to provide a kind of little
Type and can possess high optical property to what all aberrations maked corrections well in whole zoom region
Zoom lens.Further, the present invention also aims to provide a kind of small-sized and heavy caliber, high power
The zoom lens of rate.Can be for from visible domain additionally, the present invention also aims to offer one
Light to near-infrared territory makes the zoom lens that produced all aberrations make corrections well.
For the method solving problem
In order to solve above-mentioned problem, it is achieved purpose, the zoom lens of the present invention possess: from object side
The 1st battery of lens with negative power configured successively, the 2nd battery of lens with positive light coke,
3 battery of lens, and carry out zoom, described change by the change at the interval on the optical axis of each battery of lens
Focus lens is characterised by, plus lens that described 2nd battery of lens includes configuring successively from object side,
Minus lens, plus lens, described 3rd battery of lens is according to the mode structure being configured with minus lens in most object side
Become, and meet conditional shown below,
(1)2.8≤|β2T/β2W|≤12.0
Wherein, β 2T represents the multiplying power of the telescope end of described 2nd battery of lens, and β 2W represents the described 2nd
The multiplying power of the wide-angle side of battery of lens.
In accordance with the invention it is possible to provide small-sized and can in whole zoom region to all aberrations well
Carry out the zoom lens possessing high optical property maked corrections.
Further, the zoom lens of the present invention are based on foregoing invention, it is characterised in that by making
State the 1st battery of lens to move along optical axis and carry out zoom, saturating by make after described 2nd battery of lens
Mirror group moves along optical axis, and the image planes variation to causing along with zoom makes corrections, described by making
1st battery of lens moves along optical axis direction object side, thus carries out from infinity object focus state to
The focusing of closer object focus state.
In accordance with the invention it is possible to image planes variation during suppression zoom and during focus, and maintain good light
Learn performance.
Further, the zoom lens of the present invention are based on foregoing invention, it is characterised in that also meet with
Conditional shown in lower,
(2)-0.5≤β2W≤-0.1
Wherein, β 2W represents the multiplying power of wide-angle side of described 2nd battery of lens.
In accordance with the invention it is possible to make the coma, the image planes that are produced by the 2nd battery of lens in wide-angle side curved
Song is suppressed, thus realizes zoom lens that are small-sized and that possess high optical property.
Further, the zoom lens of the present invention are based on foregoing invention, it is characterised in that also meet with
Conditional shown in lower,
(3)-4.50≤β2T≤-1.45
Wherein, β 2T represents the multiplying power of telescope end of described 2nd battery of lens..
In accordance with the invention it is possible to make the coma, the image planes that are produced by the 2nd battery of lens at telescope end curved
Song is suppressed, thus realizes zoom lens that are small-sized and that possess high optical property.
Further, the zoom lens of the present invention are based on foregoing invention, it is characterised in that also meet with
Conditional shown in lower,
(4)0.3≤βLT≤1.0
Wherein, β LT represents the multiplying power at the telescope end of the battery of lens that image side is configured.
In accordance with the invention it is possible to make at telescope end by the sphere produced at the battery of lens that image side is configured
Aberration, curvature of the image are suppressed, thus realize zoom lens that are small-sized and that possess high optical property.
Further, the zoom lens of the present invention are based on foregoing invention, it is characterised in that described
2 battery of lens possess the opening diaphragm of opening for determining regulation, from wide-angle side to telescope end
During zoom, described opening diaphragm moves to object side from image side together with described 2nd battery of lens.
In accordance with the invention it is possible to provide small-sized and heavy caliber, powerful zoom lens.
Further, the zoom lens of the present invention are based on foregoing invention, it is characterised in that also meet with
Conditional shown in lower,
(5)0.35≤|f1|/f2≤0.85
Wherein, f1 represents the focal length of described 1st battery of lens, and f2 represents the focal length of described 2nd battery of lens.
According to the present invention, the 1st battery of lens the spherical aberration produced, curvature of the image can be by the 2
Battery of lens suitably makes corrections, and is obtained in that high optical property.
Further, the zoom lens of the present invention are based on foregoing invention, it is characterised in that also meet with
Conditional shown in lower,
(6)0.2≤|f2/f3|≤1.0
Wherein, f2 represents the focal length of described 2nd battery of lens, and f3 represents the focal length of described 3rd battery of lens.
According to the present invention, the 2nd battery of lens the coma produced, curvature of the image can be by the 3
Battery of lens suitably makes corrections, and is obtained in that high optical property.
Further, the zoom lens of the present invention are based on foregoing invention, it is characterised in that the described 1st
Battery of lens is constituted according to the mode at least including one piece of plus lens and one piece of minus lens, and meet below
Shown conditional,
(7)vd1p≤41.0
(8)vd1n≥50.0
Wherein, vd1p represents the Abbe number to d line of the plus lens included in described 1st battery of lens,
Vd1n represents the Abbe number to d line of the minus lens included in described 1st battery of lens.
In accordance with the invention it is possible to the chromatic aberration making the minus lens comprised by the 1st battery of lens produce is able to
Good correction, and also spherical aberration, curvature of the image can be maked corrections well such that it is able to
Obtain high optical property.Particularly, it is possible to for making to be produced from visible domain to the light in near-infrared territory
Aberration make corrections well.
Further, the zoom lens of the present invention are based on foregoing invention, it is characterised in that also meet with
Conditional shown in lower,
(9)vd2pa≥68.0
Wherein, vd2pa represents the Abbe to d line of the plus lens included in described 2nd battery of lens
The meansigma methods of number.
In accordance with the invention it is possible to make by the 2nd battery of lens produce from visible domain to the light in near-infrared territory
Corresponding chromatic aberration is well maked corrections, and is obtained in that high optical property.
Further, the zoom lens of the present invention are based on foregoing invention, it is characterised in that the described 1st
Battery of lens is configured to, and is configured with minus lens, minus lens, plus lens from object side the most continuously.
In accordance with the invention it is possible to make all aberrations produced by the 1st battery of lens be suppressed.
Further, the zoom lens of the present invention are based on foregoing invention, it is characterised in that the described 3rd
Battery of lens is configured to, and is configured with minus lens, plus lens from object side the most continuously.
According to the present invention, the 1st, the 2nd battery of lens the curvature of the image, the coma that produce can lead to
Cross the 3rd battery of lens to make corrections.
Further, the zoom lens of the present invention are based on foregoing invention, it is characterised in that the described 3rd
The minus lens configured in most object side of battery of lens make concave surface towards object side,
And meet conditional shown below,
(10)-1.5≤(R31+R32)/(R31-R32)≤0.3
Wherein, R31 represents the object of the minus lens configured in most object side of described 3rd battery of lens
The radius of curvature of side, R32 represents the minus lens configured in most object side of described 3rd battery of lens
The radius of curvature of image side surface.
According to the present invention, the 1st, the 2nd battery of lens the curvature of the image produced can pass through the 3rd lens
Group well makes corrections.
Further, the zoom lens of the present invention are based on foregoing invention, it is characterised in that also meet with
Conditional shown in lower,
(11)4.5≤|X2|2/(|f1|×f2)≤16.5
Wherein, X2 represents the movement from wide-angle side to described 2nd battery of lens during zoom of telescope end
Amount, f1 represents the focal length of described 1st battery of lens, and f2 represents the focal length of described 2nd battery of lens.
The amount of movement X2 of the 2nd battery of lens refers to, relative to fixed in the limited distance on optical axis
A bit, the shifting the optical axis of the 2nd battery of lens when the 2nd battery of lens moves to telescope end from wide-angle side
Momentum.
According to the present invention, by from wide-angle side to the movement of the 2nd battery of lens during the zoom of telescope end
Amount is appropriately configured, it is possible to realize the shortening of optical system total length under the maintenance of optical property.
Further, the zoom lens of the present invention are based on foregoing invention, it is characterised in that also meet with
Conditional shown in lower,
(12)0.3≤f2/fLw≤1.1
Wherein, f2 represents the focal length of described 2nd battery of lens, after fLw represents described 3rd battery of lens
The synthesis focal length in wide-angle side of all of battery of lens configured.
According to the present invention, the coma produced by the 2nd battery of lens in wide-angle side can be saturating by the 3rd
Battery of lens after mirror group well makes corrections.
Invention effect
According to the present invention, play and can provide a kind of small-sized and can be in whole zoom region to all pictures
Difference carries out the such effect of the zoom lens possessing high optical property maked corrections well.Further, also rise
To providing a kind of small-sized and heavy caliber, the such effect of powerful zoom lens.Additionally,
Also acting as that offer is a kind of can be for making produced all aberrations from visible domain to the light in near-infrared territory
The such effect of zoom lens well maked corrections.
Accompanying drawing explanation
Fig. 1 is the sectional view along optical axis of the structure of the zoom lens representing embodiment 1.
Fig. 2 is all aberration diagrams of the zoom lens of embodiment 1.
Fig. 3 is the sectional view along optical axis of the structure of the zoom lens representing embodiment 2.
Fig. 4 is all aberration diagrams of the zoom lens of embodiment 2.
Fig. 5 is the sectional view along optical axis of the structure of the zoom lens representing embodiment 3.
Fig. 6 is all aberration diagrams of the zoom lens of embodiment 3.
Fig. 7 is the sectional view along optical axis of the structure of the zoom lens representing embodiment 4.
Fig. 8 is all aberration diagrams of the zoom lens of embodiment 4.
Fig. 9 is the sectional view along optical axis of the structure of the zoom lens representing embodiment 5.
Figure 10 is all aberration diagrams of the zoom lens of embodiment 5.
Figure 11 is the sectional view along optical axis of the structure of the zoom lens representing embodiment 6.
Figure 12 is all aberration diagrams of the zoom lens of embodiment 6.
Figure 13 is the sectional view along optical axis of the structure of the zoom lens representing embodiment 7.
Figure 14 is all aberration diagrams of the zoom lens of embodiment 7.
Description of reference numerals
G11、G21、G31、G41、G51、G61、G711st battery of lens
G12、G22、G32、G42、G52、G62、G722nd battery of lens
G13、G23、G33、G43、G53、G63、G733rd battery of lens
G744th battery of lens
L111、L112、L114、L122、L131、L211、L212、L214、L222、L231、L311、L312、
L314、L322、L331、L411、L412、L414、L422、L431、L511、L512、L514、L522、L531、
L611、L612、L614、L622、L631、L711、L712、L714、L722、L731Minus lens
L113、L121、L123、L132、L133、L213、L221、L223、L232、L233、L313、L321、
L323、L332、L333、L413、L421、L423、L432、L433、L513、L521、L523、L532、L533、
L613、L621、L623、L632、L633、L713、L721、L723、L732、L741Plus lens
STP opening diaphragm
CG protects glass
IMG imaging surface
Detailed description of the invention
Hereinafter, the preferred implementation of the zoom lens of the present invention is described in detail.
The zoom lens structure of the present invention is, possess configure successively from object side there is negative power
The 1st battery of lens, the 2nd battery of lens with positive light coke and the 3rd battery of lens.Further, pass through
Change the interval on the optical axis of each battery of lens to carry out zoom.
It is an object of the invention to, first, it is provided that a kind of small-sized and can be in whole zoom region pair
All aberrations carry out the zoom lens possessing high optical property maked corrections well.Therefore, in order to realize this
Purpose, sets various conditions shown below.
In order to realize zoom lens that are small-sized and that possess high optical property, preferably make to be responsible for the saturating of zoom
The focal power of mirror group increases, and along with amount of movement produced by zoom reduces.But, if it is burnt to increase light
Spending, the trend that the generating capacity of aberration also increases exists, it is difficult to maintain high optical property.Therefore, in order to
Realize zoom lens that are small-sized and that possess high optical property, need the saturating of the battery of lens to responsible zoom
Mirror structure, it is appropriately configured in the multiplying power of wide-angle side, each battery of lens of telescope end.
In the zoom lens of the present invention, it is the most saturating that the 2nd battery of lens includes configuring successively from object side
Mirror, minus lens, plus lens.In the 2nd battery of lens, produce the plus lens configured in most object side
Raw spherical aberration, curvature of the image, chromatic aberration, by the minus lens configured after this plus lens,
Plus lens makes corrections.It addition, in the 2nd battery of lens, configure plus lens in most object side, it becomes possible to
Make incident ray converge by this plus lens, and be capable of the path of the lens after the 2nd battery of lens
Change.
3rd battery of lens is constituted according to the mode being configured with minus lens in most object side.By utilizing this to bear
Lens make beam divergence incident near optical axis, and can enter the curvature of the image of telescope end well
Row correction.
Further, in the zoom lens of the present invention, on the premise of said structure, as preferably, incite somebody to action
The multiplying power of the telescope end of the 2nd battery of lens is set to β 2T, the multiplying power of the wide-angle side of the 2nd battery of lens is set to
During β 2W, meet following conditional.
(1)2.8≤|β2T/β2W|≤12.0
The multiplying power of the telescope end of conditional (1) regulation the 2nd battery of lens and the ratio of the multiplying power of wide-angle side.
By meeting conditional (1), it is possible to realize the miniaturization (shortening of optical system total length of optical system
Change), and suppress along with the generation of the curvature of the image caused to the zoom of telescope end from wide-angle side,
And high optical property is maintained in whole zoom region.
If less than the lower limit of conditional (1), then the impact for the zoom of the 2nd battery of lens is excessive,
The curvature of the image produced along with zoom increases, and its correction is difficult to.On the other hand, if exceeding
The higher limit of conditional (1), then the impact for the zoom of the 2nd battery of lens diminishes, therefore zoom
Time the 2nd battery of lens amount of movement increase, and carry out optical system total length shortening difficulty.
If it should be noted that above-mentioned conditional (1) meets scope as follows, then can the phase
Treat more excellent effect.
(1a)4.0≤|β2T/β2W|≤10.9
By meeting the scope specified by this conditional (1a), it is possible to realize more small-sized and possess
The zoom lens of high optical property.
If it addition, above-mentioned conditional (1a) meets scope as follows, then it is capable of further
Small-sized and possess the zoom lens of high optical property.
(1b)5.0≤|β2T/β2W|≤9.8
It addition, in the zoom lens of the present invention, can move along optical axis by making the 1st battery of lens
Carry out zoom, moved along optical axis by the battery of lens after making the 2nd battery of lens, make corrections along with
Zoom and cause image planes variation, by making the 1st battery of lens move along optical axis direction object side, enter
Row is from the focusing of infinity object focus state to minimum distance object focus state.
By mainly making the 1st battery of lens undertake anamorphosis function, and make the battery of lens after the 2nd battery of lens
Undertake the correction of the image planes variation caused along with zoom, it is possible to carry out the benefit of image planes variation efficiently
Just.It addition, by making the 1st battery of lens bear focus, it is possible to the picture that suppression causes along with focus
Face changes such that it is able to maintain optical property well.
Further, in the zoom lens of the present invention, as preferably, by the wide-angle side of the 2nd battery of lens
When multiplying power is set to β 2W, meet following conditional.
(2)-0.5≤β2W≤-0.1
The multiplying power of the wide-angle side of conditional (2) regulation the 2nd battery of lens.By meeting conditional (2),
The coma, the curvature of the image that are produced by the 2nd battery of lens in wide-angle side can be made to be suppressed, thus
Realize zoom lens that are small-sized and that possess high optical property.
If less than the lower limit of conditional (2), then the focal power of the 2nd battery of lens is the most weak, optical system
The total length of system extends, and makes the miniaturization difficult of optical system.On the other hand, if exceeding conditional (2)
Higher limit, then the focal power of the 2nd battery of lens is too strong, and make wide-angle side produce coma,
The correction difficulty of curvature of the image.
If it should be noted that above-mentioned conditional (2) meets scope as follows, then can the phase
Treat more excellent effect.
(2a)-0.45≤β2W≤-0.15
By meeting the scope specified by this conditional (2a), it is possible to realize more small-sized and possess
The zoom lens of high optical property.
If it addition, above-mentioned conditional (2a) meets scope as follows, it is possible to realize the least
Type and possess the zoom lens of high optical property.
(2b)-0.3≤β2W≤-0.2
Further, in the zoom lens of the present invention, as preferably, by the telescope end of the 2nd battery of lens
When multiplying power is set to β 2T, meet following conditional.
(3)-4.50≤β2T≤-1.45
The multiplying power of the telescope end of conditional (3) regulation the 2nd battery of lens.By meeting conditional (3),
The coma, the curvature of the image that are produced by the 2nd battery of lens at telescope end can be made to be suppressed, thus
Realize zoom lens that are small-sized and that possess high optical property.
If less than the lower limit of conditional (3), then the focal power of the 2nd battery of lens is the most weak, optical system
The total length of system extends, and makes the miniaturization difficult of optical system.On the other hand, if exceeding conditional (3)
Higher limit, then the focal power of the 2nd battery of lens is too strong, and make telescope end produce coma,
The correction difficulty of curvature of the image.
If it should be noted that above-mentioned conditional (3) meets scope as follows, then can the phase
Treat more excellent effect.
(3a)-4.0≤β2T≤-2.0
By meeting the scope specified by this conditional (3a), it is possible to realize more small-sized and possess
The zoom lens of high optical property.
If it addition, above-mentioned conditional (3a) meets scope as follows, it is possible to realize the least
Type and possess the zoom lens of high optical property.
(3b)-3.5≤β2T≤-2.5
Further, in the zoom lens of the present invention, as preferably, by the lens that image side is configured
When the multiplying power of the telescope end of group is set to β LT, meet following conditional.
(4)0.3≤βLT≤1.0
Conditional (4) regulation is in the multiplying power of the telescope end of the battery of lens that image side is configured.By full
Foot conditional (4), it is possible to make at telescope end by the sphere mapping produced at the battery of lens that image side is configured
Difference, curvature of the image are suppressed, thus are realized zoom lens that are small-sized and that possess high optical property.
If less than the lower limit of conditional (4), then in the focal power of the battery of lens that image side is configured
Too strong, and make the correction difficulty of the spherical aberration in telescope end generation, curvature of the image.On the other hand,
If exceeding the higher limit of conditional (4), then the focal power at the battery of lens that image side is configured is the most weak,
The total length of optical system extends, and makes the miniaturization difficult of optical system.
If it should be noted that above-mentioned conditional (4) meets scope as follows, then can the phase
Treat more excellent effect.
(4a)0.4≤βLT≤0.9
By meeting the scope specified by this conditional (4a), it is possible to realize more small-sized and possess
The zoom lens of high optical property.
If it addition, above-mentioned conditional (4a) meets scope as follows, it is possible to realize the least
Type and possess the zoom lens of high optical property.
(4b)0.5≤βLT≤0.8
Further, it is an object of the invention to provide small-sized and heavy caliber, powerful zoom lens.
Therefore, in order to realize this purpose, use structure as shown below.
That is, in the zoom lens of the present invention, possess for determining opening of regulation in the 2nd battery of lens
The opening diaphragm (also referred to as aperture diaphragm) of mouth, when carrying out zoom from wide-angle side to telescope end, opening
Diaphragm moves to object side from image side together with the 2nd battery of lens.
In the case of being intended to the optical system realizing becoming clear, need to increase the opening footpath of opening diaphragm, but
Increase opening footpath can the external diameter of optical system be impacted, it is difficult to constitute the optical system of path.?
In the zoom lens of the present invention, as it has been described above, the most object side at the 2nd battery of lens is configured with plus lens,
By utilizing this plus lens to make incident ray converge, thus the lens after realizing the 2nd battery of lens is little
Footpath.Therefore, in the zoom lens of the present invention, by possessing opening diaphragm in the 2nd battery of lens,
The optical system become clear can be realized in the case of not expanding optical system external diameter.
It addition, in the case of opening diaphragm is fixing, when carrying out zoom, opening diaphragm becomes obstruction
And make the amount of movement of each battery of lens be restricted, and make high magnificationization difficulty and optical aberration correcting the most difficult.
If being intended to when by fixing for opening diaphragm, it is achieved high magnification and possess the change of good optical property
Focus lens, then must assure that the moving area of each battery of lens has more than needed, and cause the big of optical system
Type (optical system total length is elongated) such problem produces.Therefore, at the zoom lens of the present invention
In, opening diaphragm is arranged in the 2nd battery of lens, by making opening diaphragm and when carrying out zoom
2 battery of lens move together, thus also are able to substantially ensure that each battery of lens in limited region
Amount of movement, it is possible to realize miniaturization, high magnification, and improve optical property.0073
Further, in the zoom lens of the present invention, as preferably, the focal length of the 1st battery of lens is set to
F1, when the focal length of the 2nd battery of lens is set to f2, meets following conditional.
(5)0.35≤|f1|/f2≤0.85
The focal length of conditional (5) regulation the 1st battery of lens and the ratio of the focal length of the 2nd battery of lens.Pass through
Meet conditional (5), the 1st battery of lens the spherical aberration, the curvature of the image that produce can be by the 2
Battery of lens suitably makes corrections such that it is able to obtain high optical property.
If less than the lower limit of conditional (5), then the focal power of the 1st battery of lens is too strong, therefore by
The curvature of the image that 1st battery of lens produces is excessive, it is impossible to make this curvature of the image be able to by the 2nd battery of lens
Make corrections.On the other hand, if exceeding the higher limit of conditional (5), then the light of the 2nd battery of lens is burnt
Spending strong, the correction of the spherical aberration therefore produced by the 1st battery of lens is excessive, thus obtains high optics
Performance difficulty.
If it should be noted that above-mentioned conditional (5) meets scope as follows, then can the phase
Treat more excellent effect.
(5a)0.4≤|f1|/f2≤0.7
By meeting the scope specified by this conditional (5a), it is possible to realize possessing more high optical property
Zoom lens.
If it addition, above-mentioned conditional (5a) meets scope as follows, then it is capable of further
Possess the zoom lens of high optical property.
(5b)0.5≤|f1|/f2≤0.7
Further, in the zoom lens of the present invention, as preferably, the focal length of the 2nd battery of lens is set to
F2, when the focal length of the 3rd battery of lens is set to f3, meets following conditional.
(6)0.2≤|f2/f3|≤1.0
The focal length of conditional (6) regulation the 2nd battery of lens and the ratio of the focal length of the 3rd battery of lens.Pass through
Meet conditional (6), the 2nd battery of lens the coma, the curvature of the image that produce can be by the 3
Battery of lens suitably makes corrections such that it is able to obtain high optical property.
If less than the lower limit of conditional (6), then the focal power of the 3rd battery of lens is too strong, therefore without
Curvature of the image is suitably maked corrections by method.On the other hand, if exceeding the higher limit of conditional (6),
Then the focal power of the 2nd battery of lens is too strong, and therefore the generation of coma is notable, by the 3rd battery of lens
Carry out this correction difficulty.
If it should be noted that above-mentioned conditional (6) meets scope as follows, then can the phase
Treat more excellent effect.
(6a)0.3≤|f2/f3|≤0.9
By meeting the scope specified by this conditional (6a), it is possible to realize possessing more high optical property
Zoom lens.
If it addition, above-mentioned conditional (6a) meets scope as follows, then it is capable of further
Possess the zoom lens of high optical property.
(6b)0.4≤|f2/f3|≤0.8
Further, it is an object of the invention to, it is provided that one can for from visible domain to near-infrared territory
Light make the zoom lens that produced all aberrations make corrections well.Therefore, in order to realize this purpose,
Set various conditions shown below.
In the zoom lens of the present invention, as preferably, the 1st battery of lens is configured at least include one
Piece plus lens and one piece of minus lens.Further, as preferably, the most saturating by included in the 1st battery of lens
The Abbe number to d line of mirror is set to vd1p, by the minus lens included in the 1st battery of lens to d line
Abbe number when being set to vd1n, meet following conditional.
(7)vd1p≤41.0
(8)vd1n≥50.0
The Abbe number to d line of the plus lens included in conditional (7) regulation the 1st battery of lens,
Represent for the chromatic aberration produced by the minus lens included in the 1st battery of lens is maked corrections well
Condition.It addition, conditional (8) regulation the 1st battery of lens included in minus lens to d line
Abbe number, represent for make by the 1st battery of lens produce chromatic aberration reduce while also to sphere
Aberration, curvature of the image carry out the condition maked corrections well.
By meeting conditional (7), (8), it is possible to make the minus lens comprised by the 1st battery of lens produce
Raw chromatic aberration is well maked corrections, and also can carry out spherical aberration, curvature of the image well
Correction, thus obtain high optical property.Particularly, for from visible domain to the luminous energy in near-infrared territory
Produced aberration is enough made well to be maked corrections.
If less than the higher limit of conditional (7), then by the 1st battery of lens produce from visible domain to
On axle corresponding to the light in near-infrared territory, chromatic aberration, multiplying power chromatic aberration increase, and cause optical property to show
Write deterioration.
If it should be noted that above-mentioned conditional (7) meets scope as follows, then can the phase
Treat more excellent effect.
(7a)vd1p≤33.5
By meeting the scope specified by this conditional (7a), it is possible to realize possessing more high optical property
Zoom lens.
If it addition, above-mentioned conditional (7a) meets scope as follows, then it is capable of further
Possess the zoom lens of high optical property.
(7b)vd1p≤26.0
If less than the lower limit of conditional (8), then by the 1st battery of lens produce from visible domain to
On axle corresponding to the light in near-infrared territory, chromatic aberration increases, and causes optical property significantly to deteriorate.
If it should be noted that above-mentioned conditional (8) meets scope as follows, then can the phase
Treat more excellent effect.
(8a)vd1n≥55.0
By meeting the scope specified by this conditional (8a), it is possible to realize possessing more high optical property
Zoom lens.
If it addition, above-mentioned conditional (8a) meets scope as follows, then it is capable of further
Possess the zoom lens of high optical property.
(8b)vd1n≥60.0
Further, in the zoom lens of the present invention, as preferably, included in the 2nd battery of lens
When the meansigma methods to the Abbe number of d line of plus lens is set to vd2pa, meet conditional as follows.
(9)vd2pa≥68.0
The Abbe number to d line of the plus lens included in conditional (9) regulation the 2nd battery of lens
Meansigma methods, represent for make by the 2nd battery of lens produce from visible domain to the light in near-infrared territory institute right
The condition that the chromatic aberration answered well is maked corrections.
If less than the lower limit of conditional (9), then be difficult to by the 2nd battery of lens produce from can
See that area of light arrives the correction of the chromatic aberration corresponding to the light in near-infrared territory, and cause optical property the most bad
Change.
If it should be noted that above-mentioned conditional (9) meets scope as follows, then can the phase
Treat more excellent effect.
(9a)vd2pa≥72.0
By meeting the scope specified by this conditional (9a), it is possible to realize possessing more high optical property
Zoom lens.
If it addition, above-mentioned conditional (9a) meets scope as follows, then it is capable of further
Possess the zoom lens of high optical property.
(9b)vd2pa≥76.0
Further, in the zoom lens of the present invention, the 1st battery of lens can be configured to from object side
It is configured with minus lens, minus lens, plus lens the most continuously.In such manner, it is possible to make to be produced by negative power
Aberration be dispersed by the configuration of two pieces of minus lenses, it is possible to make spherical aberration, curvature of the image
Reduce.It addition, the spherical aberration produced by two pieces of minus lenses, curvature of the image can be by these
The plus lens that the image side of two pieces of minus lenses is configured makes corrections.Therefore, it is possible to make by the 1st battery of lens
The spherical aberration, the curvature of the image that produce effectively are maked corrections.
Further, in the zoom lens of the present invention, the 3rd battery of lens can be configured to from object side
It is configured with minus lens, plus lens the most continuously.So, the 1st, the 2nd battery of lens the image planes produced
Bending, coma can be maked corrections by the 3rd battery of lens.Specifically, by the 1st, the 2nd
The curvature of the image that battery of lens produces can be maked corrections by the minus lens of the 3rd battery of lens.It addition, by
The coma that 1st, the 2nd battery of lens produces can be maked corrections by the plus lens of the 3rd battery of lens.
Further, in the zoom lens of the present invention, for the image planes produced by the 1st, the 2nd battery of lens
Curving through the 3rd battery of lens to make corrections, as preferably, bearing of the most object side of the 3rd battery of lens is saturating
Mirror configures making concave surface in the way of object side.Further, as it is further preferred that by the 3rd battery of lens
The radius of curvature of the object side of the minus lens that most object side is configured is set to R31, by the 3rd battery of lens
The radius of curvature of the image side surface of minus lens that configured of most object side when being set to R32, meet following
Conditional.
(10)-1.5≤(R31+R32)/(R31-R32)≤0.3
The object side of the concavees lens that the most object side of conditional (10) regulation the 3rd battery of lens is configured
Radius of curvature and the radius of curvature of image side surface.By meeting conditional (10), by the 1st, the 2nd
The curvature of the image that battery of lens produces can be maked corrections well by the 3rd battery of lens.
If less than the lower limit of conditional (10), the then correction of the curvature of the image carried out by these concavees lens
Excessive, and good optical property cannot be obtained.On the other hand, if exceeding the upper of conditional (10)
Limit value, then the correction of the curvature of the image carried out by these concavees lens is not enough, and cannot obtain good optics
Performance.
If it should be noted that above-mentioned conditional (10) meets scope as follows, then can the phase
Treat more excellent effect.
(10a)-1.2≤(R31+R32)/(R31-R32)≤0.2
By meeting the scope specified by this conditional (10a), it is possible to realization possesses the highest optical
The zoom lens of energy.
If it addition, above-mentioned conditional (10a) meets scope as follows, being then capable of into one
Step possesses the zoom lens of high optical property.
(10b)-0.8≤(R31+R32)/(R31-R32)≤0.1
Further, in the zoom lens of the present invention, as preferably, will carry out to telescope end from wide-angle side
The amount of movement of the 2nd battery of lens during zoom is set to X2, and the focal length of the 1st battery of lens is set to f1, will
When the focal length of the 2nd battery of lens is set to f2, meet following conditional.
(11)4.5≤|X2|2/(|f1|×f2)≤16.5
The amount of movement X2 of the 2nd battery of lens refers to, relative to fixed in the limited distance on optical axis
A bit, the shifting the optical axis of the 2nd battery of lens when the 2nd battery of lens moves to telescope end from wide-angle side
Momentum.
Conditional (11) regulation from wide-angle side to telescope end carry out zoom time the movement of the 2nd battery of lens
The relation of the focal length of amount and the focal length of the 1st battery of lens and the 2nd battery of lens.By meeting conditional (11),
Can to from wide-angle side to telescope end carry out zoom time the amount of movement of the 2nd battery of lens suitably set
Fixed such that it is able under the maintenance of optical property, to realize the shortening of optical system total length.
If being less than the lower limit of conditional (11), although the 2nd battery of lens when then can make zoom
Amount of movement reduces, but is difficult to the aberration that suppression causes along with zoom.On the other hand, if exceeding condition
The higher limit of formula (11), then the amount of movement of the 2nd battery of lens during zoom increases, and optical system is complete
Long prolongation.
If it should be noted that above-mentioned conditional (11) meets scope as follows, then can the phase
Treat more excellent effect.
(11a)6.8≤|X2|2/(|f1|×f2)≤15.2
By meeting the scope specified by this conditional (11a), it is possible to realize more small-sized and tool
The zoom lens of standby high optical property.
If it addition, above-mentioned conditional (11a) meets scope as follows, being then capable of into one
Walk zoom lens that are small-sized and that possess high optical property.
(11b)7.5≤|X2|2/(|f1|×f2)≤14.5
Further, in the zoom lens of the present invention, as preferably, the focal length of the 2nd battery of lens is set to
F2, is set to the synthesis focal length in wide-angle side of all battery of lens configured after the 3rd battery of lens
During fLw, meet following conditional.
(12)0.3≤f2/fLw≤1.1
Configured after the focal length of conditional (12) regulation the 2nd battery of lens and the 3rd battery of lens is all
The ratio of the synthesis focal length in wide-angle side of battery of lens.By meeting conditional (12), wide-angle side by
The coma that 2nd battery of lens produces can be carried out well by the battery of lens after the 3rd battery of lens
Correction.
If less than the lower limit of conditional (12), the then focal power of the battery of lens after the 3rd battery of lens
Cross weak, therefore the coma produced by the 2nd battery of lens is carried out well correction difficulty.The opposing party
Face, if exceeding the higher limit of conditional (12), then the focal power of the 2nd battery of lens is the most weak, therefore light
The shortening difficulty of system total length.
If it should be noted that above-mentioned conditional (12) meets scope as follows, then can the phase
Treat more excellent effect.
(12a)0.48≤f2/fLw≤0.92
By meeting the scope specified by this conditional (12a), it is possible to realize more small-sized and tool
The zoom lens of standby high optical property.
It addition, above-mentioned conditional (12a) meets scope as follows, it is possible to realize the least
Type and possess the zoom lens of high optical property.
(12b)0.55≤f2/fLw≤0.85
As described above, according to the present invention, by possessing said structure, it is possible to realize small-sized,
And the zoom possessing high optical property that in whole zoom region, all aberrations can be maked corrections well
Lens.Further, play and be capable of small-sized and heavy caliber, the such effect of powerful zoom lens
Really.Furthermore it is possible to realize for making produced all aberrations good from visible domain to the light in near-infrared territory
Carry out well the zoom lens maked corrections.
Hereinafter, with reference to the accompanying drawings the embodiment of the zoom lens of the present invention is described in detail.Need
Bright, the present invention is not limited by below example.
[embodiment 1]
Fig. 1 is the sectional view along optical axis of the structure of the zoom lens representing embodiment 1.This zoom
Lens are configured to, and are configured with the 1st battery of lens with negative power from not shown object side successively
G11, there is the 2nd battery of lens G of positive light coke12, there is the 3rd battery of lens G of positive light coke13。
It addition, at the 3rd battery of lens G13And it is configured with protection glass CG between imaging surface IMG.
1st battery of lens G11It is configured to from object side be configured with successively minus lens L111, minus lens L112、
Plus lens L113, minus lens L114.Minus lens L112With plus lens L113Engage.At plus lens L113
Imaging surface IMG side be formed with aspheric surface.
2nd battery of lens G12It is configured to from object side be configured with successively plus lens L121, be used for determining
Opening diaphragm STP, the minus lens L of the bore of regulation122, plus lens L123.At plus lens L121's
Two sides is formed with aspheric surface.Minus lens L122With plus lens L123Engage.
3rd battery of lens G13It is configured to from object side be configured with successively minus lens L131, plus lens L132、
Plus lens L133.Minus lens L131Object side be concave surface.At plus lens L133Two sides be formed
Aspheric surface.
In these zoom lens, by making the 1st battery of lens G11Along optical axis to be formed to imaging surface
The mode of the track that IMG side is protruded moves, thus carries out from wide-angle side to the zoom of telescope end.It addition,
By making the 2nd battery of lens G12Move along optical axis from the lateral object side of imaging surface IMG and make the 3rd
Battery of lens G13Move in the way of the track that object side protrudes gently to be formed along optical axis, thus enter
The correction of the position of the imaging surface IMG that row causes along with zoom.Now, opening diaphragm STP with
2nd battery of lens G12Move together.Further, by making the 1st battery of lens G11Along optical axis direction object
Side shifting, thus carry out gathering from infinity object focus state to minimum distance object focus state
Burnt.
Below, it is shown that the various numeric datas relevant to the zoom lens of embodiment 1.
Focal length=3.19 (wide-angle side) of zoom lens whole system~19.44 (telescope ends)
F value (FNO)=1.23 (wide-angle side)~3.44 (telescope ends)
Angle of half field-of view (ω)=58.37 (wide-angle side)~8.53 (telescope ends)
1st battery of lens G11Focal length (f1)=-8.91
2nd battery of lens G12Focal length (f2)=13.42
3rd battery of lens G13Focal length (f3)=20.43
Zoom ratio=6.10
(lens data)
r1=157.592
d1=0.50 nd1=1.83 vd1=42.72
r2=9.500
d2=5.28
r3=-56.402
d3=0.50 nd2=1.49 vd2=70.44
r4=19.091
d4=3.86 nd3=1.82 vd3=24.06
r5=-48.424 (aspheric surfaces)
d5=1.02
r6=-16.500
d6=0.50 nd4=1.52 vd4=64.20
r7=47.208
d7=D (7) (variable)
r8=12.507 (aspheric surfaces)
d8=3.83 nd5=1.55 vd5=71.68
r9=-21.857 (aspheric surfaces)
d9=0.71
r10=∞ (opening diaphragm)
d10=1.57
r11=31.697
d11=0.50 nd6=1.72 vd6=29.50
r12=9.003
d12=4.03 nd7=1.44 vd7=95.10
r13=-17.916
d13=D (13) (variable)
r14=-9.959
d14=0.50 nd8=1.58 vd8=40.89
r15=11.066
d15=0.68
r16=15.141
d16=1.83 nd9=1.88 vd9=40.81
r17=-39.802
d17=0.50
r18=49.128 (aspheric surfaces)
d18=2.92 nd10=1.50 vd10=81.56
r19=-9.723 (aspheric surfaces)
d19=D (19) (variable)
r20=∞
d20=1.50 nd11=1.52 vd11=64.20
r21=∞
d21=4.00
r22=∞ (imaging surface)
Circular cone coefficient (k) and asphericity coefficient (A, B, C, D, E)
(the 5th face)
K=0,
A=0,
B=-6.72458 × 10-5, C=-2.40695 × 10-7,
D=2.61052 × 10-9, E=-3.95672 × 10-11
(the 8th face)
K=0,
A=0,
B=-9.69395 × 10-5, C=-9.51005 × 10-7,
D=4.02158 × 10-8, E=-6.43542 × 10-10
(the 9th face)
K=0,
A=0,
B=1.00663 × 10-4, C=-1.18082 × 10-6,
D=4.06019 × 10-8, E=-6.35633 × 10-10
(the 18th face)
K=0,
A=0,
B=5.35557 × 10-4, C=2.45046 × 10-5,
D=-1.67573 × 10-7, E=2.92909 × 10-8
(the 19th face)
K=0,
A=0,
B=8.27909 × 10-4, C=5.14824 × 10-5,
D=-2.72286 × 10-6, E=1.39662 × 10-7
(zoom data)
(numerical value relevant to conditional (1))
| β 2T/ β 2W |=5.87
β the 2T: the 2 battery of lens G12The multiplying power of telescope end
β the 2W: the 2 battery of lens G12The multiplying power of wide-angle side
(numerical value relevant to conditional (2))
β 2W=-0.43
(numerical value relevant to conditional (3))
β 2T=-2.53
(numerical value relevant to conditional (4))
β LT=0.86
β LT: at battery of lens (the 3rd battery of lens G that image side is configured13) the multiplying power of telescope end
(numerical value relevant to conditional (5))
| f1 |/f2=0.66
(numerical value relevant to conditional (6))
| f2/f3 |=0.66
(numerical value relevant to conditional (7))
Vd1p=24.06
Vd1p: the 1 battery of lens G11Included in plus lens (plus lens L113) to d line
Abbe number
(numerical value relevant to conditional (8))
Vd1n=70.44
Vd1n: the 1 battery of lens G11Included in minus lens (minus lens L112) to d line
Abbe number
(numerical value relevant to conditional (9))
Vd2pa=83.39
Vd2pa: the 2 battery of lens G12Included in the meansigma methods of the Abbe number to d line of plus lens
(numerical value relevant to conditional (10))
(R31+R32)/(R31-R32)=-0.05
R31: the 3 battery of lens G13The minus lens L configured in most object side131Object side
Radius of curvature
R32: the 3 battery of lens G13The minus lens L configured in most object side131Image side surface
Radius of curvature
(numerical value relevant to conditional (11))
|X2|2/ (| f1 | × f2)=6.73
X2: from wide-angle side to telescope end carry out zoom time the 2nd battery of lens G12Amount of movement (=
28.38)
(numerical value relevant to conditional (12))
F2/fLw=0.66
FLw: the 3 battery of lens G13The synthesis in wide-angle side of all battery of lens configured afterwards is burnt
Away from
Fig. 2 is all aberration diagrams of the zoom lens of embodiment 1.In spherical aberration diagram, the longitudinal axis represents
F value (in figure, represents with FNO), and solid line represents the wavelength being equivalent to d line (λ=587.56nm)
Characteristic, short dash line represents the characteristic of the wavelength being equivalent to g line (λ=435.84nm), long dotted line
Represent the characteristic of the wavelength being equivalent to IR line (λ=850.00nm).In astigmatism figure, the longitudinal axis represents
Angle of half field-of view (in figure, represents with ω), represents the characteristic of the wavelength being equivalent to d line.Need explanation
, in astigmatism figure, solid line represents the characteristic of sagittal plane (in figure, representing), dotted line with S
Represent the characteristic of meridional plane (in figure, representing) with M.In distortion aberration diagram, the longitudinal axis represents
Angle of half field-of view (in figure, represents with ω), represents the characteristic of the wavelength being equivalent to d line.
[embodiment 2]
Fig. 3 is the sectional view along optical axis of the structure of the zoom lens representing embodiment 2.This zoom
Lens are configured to, and are configured with the 1st battery of lens with negative power from not shown object side successively
G21, there is the 2nd battery of lens G of positive light coke22, there is the 3rd battery of lens G of positive light coke23。
It addition, at the 3rd battery of lens G23And it is configured with protection glass CG between imaging surface IMG.
1st battery of lens G21It is configured to, from object side, is configured with minus lens L successively211, minus lens
L212, plus lens L213, minus lens L214.Minus lens L212With plus lens L213Engage.At plus lens
L213Imaging surface IMG side be formed with aspheric surface.
2nd battery of lens G22It is configured to, from object side, is configured with plus lens L successively221, for really
Establish rules opening diaphragm STP, the minus lens L of fixed bore222, plus lens L223.At plus lens L221
Two sides be formed with aspheric surface.Minus lens L222With plus lens L223Engage.
3rd battery of lens G23It is configured to, from object side, is configured with minus lens L successively231, plus lens
L232, plus lens L233.Minus lens L231Object side be concave surface.At plus lens L233Two sides
It is formed with aspheric surface.
In these zoom lens, by making the 1st battery of lens G21Along optical axis to be formed to imaging surface
The mode of the track that IMG side is protruded moves, thus carries out from wide-angle side to the zoom of telescope end.It addition,
By making the 2nd battery of lens G22Move along optical axis from the lateral object side of imaging surface IMG and make the 3rd
Battery of lens G23Move in the way of the track that object side protrudes gently to be formed along optical axis, thus enter
The correction of the position of the imaging surface IMG that row causes along with zoom.Now, opening diaphragm STP with
2nd battery of lens G22Move together.Further, by making the 1st battery of lens G21Along optical axis direction object
Side shifting, thus carry out gathering from infinity object focus state to minimum distance object focus state
Burnt.
Below, it is shown that the various numeric datas relevant to the zoom lens of embodiment 2.
Focal length=3.19 (wide-angle side) of zoom lens whole system~19.44 (telescope ends)
F value (FNO)=1.23 (wide-angle side)~3.47 (telescope ends)
Angle of half field-of view (ω)=63.46 (wide-angle side)~9.03 (telescope ends)
1st battery of lens G21Focal length (f1)=-9.02
2nd battery of lens G22Focal length (f2)=13.71
3rd battery of lens G23Focal length (f3)=20.36
Zoom ratio=6.10
(lens data)
r1=579.202
d1=0.50 nd1=1.90 vd1=37.37
r2=9.500
d2=4.56
r3=-218.921
d3=0.50 nd2=1.64 vd2=55.45
r4=23.130
d4=4.30 nd3=1.82 vd3=24.06
r5=-22.947 (aspheric surfaces)
d5=0.79
r6=-12.801
d6=0.50 nd4=1.52 vd4=52.15
r7=53.596
d7=D (7) (variable)
r8=12.385 (aspheric surfaces)
d8=4.09 nd5=1.55 vd5=71.68
r9=-20.051 (aspheric surfaces)
d9=0.71
r10=∞ (opening diaphragm)
d10=1.57
r11=53.272
d11=0.60 nd6=1.67 vd6=32.17
r12=8.806
d12=4.08 nd7=1.44 vd7=95.10
r13=-17.193
d13=D (13) (variable)
r14=-8.512
d14=0.50 nd8=1.52 vd8=52.15
r15=-211.125
d15=0.57
r16=-19.080
d16=1.67 nd9=1.50 vd9=81.61
r17=-9.123
d17=0.50
r18=30.680 (aspheric surfaces)
d18=2.59 nd10=1.50 vd10=81.56
r19=-10.864 (aspheric surfaces)
d19=D (19) (variable)
r20=∞
d20=1.50 nd11=1.52 vd11=64.20
r21=∞
d21=4.00
r22=∞ (imaging surface)
Circular cone coefficient (k) and asphericity coefficient (A, B, C, D, E)
(the 5th face)
K=0,
A=0,
B=-9.10507 × 10-5, C=-5.33991 × 10-7,
D=2.86663 × 10-9, E=-7.37298 × 10-11
(the 8th face)
K=0,
A=0,
B=-9.81882 × 10-5, C=-6.15235 × 10-7,
D=2.80365 × 10-8, E=-4.53885 × 10-10
(the 9th face)
K=0,
A=0,
B=1.12174 × 10-4, C=-8.11729 × 10-7,
D=2.63785 × 10-8, E=-4.19895 × 10-10
(the 18th face)
K=0,
A=0,
B=2.38585 × 10-4, C=2.31778 × 10-5,
D=-3.13210 × 10-7, E=3.70085 × 10-8
(the 19th face)
K=0,
A=0,
B=5.36748 × 10-4, C=4.77277 × 10-5,
D=-2.53469 × 10-6, E=1.21543 × 10-7
(zoom data)
(numerical value relevant to conditional (1))
| β 2T/ β 2W |=5.88
β the 2T: the 2 battery of lens G22The multiplying power of telescope end
β the 2W: the 2 battery of lens G22The multiplying power of wide-angle side
(numerical value relevant to conditional (2))
β 2W=-0.43
(numerical value relevant to conditional (3))
β 2T=-2.53
(numerical value relevant to conditional (4))
β LT=0.85
β LT: at battery of lens (the 3rd battery of lens G that image side is configured23) the multiplying power of telescope end
(numerical value relevant to conditional (5))
| f1 |/f2=0.66
(numerical value relevant to conditional (6))
| f2/f3 |=0.67
(numerical value relevant to conditional (7))
Vd1p=24.06
Vd1p: the 1 battery of lens G21Included in plus lens (plus lens L213) to d line
Abbe number
(numerical value relevant to conditional (8))
Vd1n=52.15
Vd1n: the 1 battery of lens G21Included in minus lens (minus lens L214) to d line
Abbe number
(numerical value relevant to conditional (9))
Vd2pa=83.39
Vd2pa: the 2 battery of lens G22Included in the meansigma methods of the Abbe number to d line of plus lens
(numerical value relevant to conditional (10))
(R31+R32)/(R31-R32)=-1.08
R31: the 3 battery of lens G23The minus lens L configured in most object side231Object side
Radius of curvature
R32: the 3 battery of lens G23The minus lens L configured in most object side231Image side surface
Radius of curvature
(numerical value relevant to conditional (11))
|X2|2/ (| f1 | × f2)=6.82
X2: from wide-angle side to telescope end carry out zoom time the 2nd battery of lens G22Amount of movement (=
29.03)
(numerical value relevant to conditional (12))
F2/fLw=0.67
The synthesis in wide-angle side of all battery of lens configured after the fLw: the 3 battery of lens G23 is burnt
Away from
Fig. 4 is all aberration diagrams of the zoom lens of embodiment 2.In spherical aberration diagram, the longitudinal axis represents
F value (in figure, represents with FNO), and solid line represents the wavelength being equivalent to d line (λ=587.56nm)
Characteristic, short dash line represents the characteristic of the wavelength being equivalent to g line (λ=435.84nm), long dotted line
Represent the characteristic of the wavelength being equivalent to IR line (λ=850.00nm).In astigmatism figure, the longitudinal axis represents
Angle of half field-of view (in figure, represents with ω), represents the characteristic of the wavelength being equivalent to d line.Need explanation
, in astigmatism figure, solid line represents the characteristic of sagittal plane (in figure, representing), dotted line with S
Represent the characteristic of meridional plane (in figure, representing) with M.In distortion aberration diagram, the longitudinal axis represents
Angle of half field-of view (in figure, represents with ω), represents the characteristic of the wavelength being equivalent to d line.
[embodiment 3]
Fig. 5 is the sectional view along optical axis of the structure of the zoom lens representing embodiment 3.This zoom
Lens are configured to, and are configured with the 1st battery of lens with negative power from not shown object side successively
G31, there is the 2nd battery of lens G of positive light coke32, there is the 3rd battery of lens G of positive light coke33。
It addition, at the 3rd battery of lens G33And it is configured with protection glass between imaging surface IMG.
1st battery of lens G31It is configured to, from object side, is configured with minus lens L successively311, minus lens
L312, plus lens L313, minus lens L314.At plus lens L313Object side be formed with aspheric surface.
It addition, at minus lens L314Imaging surface IMG side be also formed with aspheric surface.
2nd battery of lens G32It is configured to, from object side, is configured with plus lens L successively321, for really
Establish rules opening diaphragm STP, the minus lens L of fixed bore322, plus lens L323.At plus lens L321
Two sides be formed with aspheric surface.Minus lens L322With plus lens L323Engage.
3rd battery of lens G33It is configured to, from object side, is configured with minus lens L successively331, plus lens
L332, plus lens L333.Minus lens L331Object side be concave surface.At plus lens L333Two sides
It is formed with aspheric surface.
In these zoom lens, by making the 1st battery of lens G31Along optical axis to be formed to imaging surface
The mode of the track that IMG side is protruded moves, thus carries out from wide-angle side to the zoom of telescope end.It addition,
By making the 2nd battery of lens G32Move along optical axis from the lateral object side of imaging surface IMG and make the 3rd
Battery of lens G33Along optical axis from object lateral imaging surface IMG side shifting, thus carry out along with zoom
The correction of the position of the imaging surface IMG caused.Now, opening diaphragm STP and the 2nd battery of lens G32
Move together.Further, by making the 1st battery of lens G31Move along optical axis direction object side, thus enter
Row is from the focusing of infinity object focus state to minimum distance object focus state.
Below, it is shown that the various numeric datas relevant to the zoom lens of embodiment 3.
Focal length=3.09 (wide-angle side) of zoom lens whole system~24.31 (telescope ends)
F value (FNO)=1.23 (wide-angle side)~5.41 (telescope ends)
Angle of half field-of view (ω)=53.02 (wide-angle side)~6.77 (telescope ends)
1st battery of lens G31Focal length (f1)=-8.72
2nd battery of lens G32Focal length (f2)=13.62
3rd battery of lens G33Focal length (f3)=20.13
Zoom ratio=7.88
(lens data)
r1=95.832
d1=0.50 nd1=1.88 vd1=40.81
r2=9.500
d2=3.14
r3=19.545
d3=0.50 nd2=1.74 vd2=49.22
r4=10.200
d4=1.77
r5=28.685 (aspheric surfaces)
d5=4.02 nd3=1.82 vd3=24.06
r6=-22.559
d6=0.57
r7=-16.524
d7=0.50 nd4=1.62 vd4=63.86
r8=39.439 (aspheric surfaces)
d8=D (8) (variable)
r9=10.268 (aspheric surfaces)
d9=4.68 nd5=1.50 vd5=81.56
r10=-22.386 (aspheric surfaces)
d10=0.71
r11=∞ (opening diaphragm)
d11=1.57
r12=14.513
d12=0.60 nd6=1.90 vd6=31.01
r13=7.283
d13=4.62 nd7=1.44 vd7=95.10
r14=-37.400
d14=D (14) (variable)
r15=-11.084
d15=0.50 nd8=1.70 vd8=41.15
r16=10.957
d16=0.66
r17=16.980
d17=1.84 nd9=1.88 vd9=40.81
r18=-21.649
d18=0.50
r19=53.019 (aspheric surfaces)
d19=2.56 nd10=1.50 vd10=81.56
r20=-9.689 (aspheric surfaces)
d20=D (20) (variable)
r21=∞
d21=1.50 nd11=1.52 vd11=64.20
r22=∞
d22=4.00
r23=∞ (imaging surface)
Circular cone coefficient (k) and asphericity coefficient (A, B, C, D, E)
(the 5th face)
K=0,
A=0,
B=1.40806 × 10-5, C=3.25534 × 10-6,
D=-4.17170 × 10-8, E=6.04485 × 10-10
(the 8th face)
K=0,
A=0,
B=-1.81784 × 10-4, C=1.95668 × 10-6,
D=-1.62257 × 10-8, E=5.45870 × 10-11
(the 9th face)
K=0,
A=0,
B=-1.20860 × 10-4, C=-1.52404 × 10-6,
D=3.61163 × 10-8, E=-5.39050 × 10-10
(the 10th face)
K=0,
A=0,
B=1.00026 × 10-4, C=-1.20395 × 10-6,
D=2.99744 × 10-8, E=-3.95433 × 10-10
(the 19th face)
K=0,
A=0,
B=4.25522 × 10-4, C=2.39298 × 10-5,
D=3.22213 × 10-7, E=3.18531 × 10-8
(the 20th face)
K=0,
A=0,
B=6.35974 × 10-4, C=6.79239 × 10-5,
D=-3.88398 × 10-6, E=1.94713 × 10-7
(zoom data)
(numerical value relevant to conditional (1))
| β 2T/ β 2W |=7.46
β the 2T: the 2 battery of lens G32The multiplying power of telescope end
β the 2W: the 2 battery of lens G32The multiplying power of wide-angle side
(numerical value relevant to conditional (2))
β 2W=-0.40
(numerical value relevant to conditional (3))
β 2T=-2.99
(numerical value relevant to conditional (4))
β LT=0.93
β LT: at battery of lens (the 3rd battery of lens G that image side is configured33) the multiplying power of telescope end
(numerical value relevant to conditional (5))
| f1 |/f2=0.64
(numerical value relevant to conditional (6))
| f2/f3 |=0.68
(numerical value relevant to conditional (7))
Vd1p=24.06
Vd1p: the 1 battery of lens G31Included in plus lens (plus lens L313) to d line
Abbe number
(numerical value relevant to conditional (8))
Vd1n=63.86
Vd1n: the 1 battery of lens G31Included in minus lens (minus lens L314) to d line
Abbe number
(numerical value relevant to conditional (9))
Vd2pa=88.33
Vd2pa: the 2 battery of lens G32Included in the meansigma methods of the Abbe number to d line of plus lens
(numerical value relevant to conditional (10))
(R31+R32)/(R31-R32)=0.04
R31: the 3 battery of lens G33The minus lens L configured in most object side331Object side
Radius of curvature
R32: the 3 battery of lens G33The minus lens L configured in most object side331Image side surface
Radius of curvature
(numerical value relevant to conditional (11))
|X2|2/ (| f1 | × f2)=10.59
X2: from wide-angle side to telescope end carry out zoom time the 2nd battery of lens G32Amount of movement (=
39.46)
(numerical value relevant to conditional (12))
F2/fLw=0.68
FLw: the 3 battery of lens G33The synthesis in wide-angle side of all of battery of lens configured afterwards
Focal length
Fig. 6 is all aberration diagrams of the zoom lens of embodiment 3.In spherical aberration diagram, the longitudinal axis represents
F value (in figure, represents with FNO), and solid line represents the wavelength being equivalent to d line (λ=587.56nm)
Characteristic, short dash line represents the characteristic of the wavelength being equivalent to g line (λ=435.84nm), long dotted line
Represent the characteristic of the wavelength being equivalent to IR line (λ=850.00nm).In astigmatism figure, the longitudinal axis represents
Angle of half field-of view (in figure, represents with ω), represents the characteristic of the wavelength being equivalent to d line.Need explanation
, in astigmatism figure, solid line represents the characteristic of sagittal plane (in figure, representing), dotted line with S
Represent the characteristic of meridional plane (in figure, representing) with M.In distortion aberration diagram, the longitudinal axis represents
Angle of half field-of view (in figure, represents with ω), represents the characteristic of the wavelength being equivalent to d line.
[embodiment 4]
Fig. 7 is the sectional view along optical axis of the structure of the zoom lens representing embodiment 4.This zoom
Lens are configured to, and are configured with the 1st battery of lens with negative power from not shown object side successively
G41, there is the 2nd battery of lens G of positive light coke42, there is the 3rd battery of lens G of positive light coke43。
It addition, at the 3rd battery of lens G43And it is configured with protection glass between imaging surface IMG.
1st battery of lens G41It is configured to, from object side, is configured with minus lens L successively411, minus lens
L412, plus lens L413, minus lens L414.At plus lens L413Object side be formed with aspheric surface.
It addition, at minus lens L414Imaging surface IMG side be also formed with aspheric surface.
2nd battery of lens G42It is configured to, from object side, is configured with plus lens L successively421, for really
Establish rules opening diaphragm STP, the minus lens L of fixed bore422, plus lens L423.At plus lens L421
Two sides be formed with aspheric surface.Minus lens L422With plus lens L423Engage.
3rd battery of lens G43It is configured to, from object side, is configured with minus lens L successively431, plus lens
L432, plus lens L433.Minus lens L431Object side be concave surface.At plus lens L433Two sides
It is formed with aspheric surface.
In these zoom lens, by making the 1st battery of lens G41Along optical axis to be formed to imaging surface
The mode of the track that IMG side is protruded moves, thus carries out from wide-angle side to the zoom of telescope end.It addition,
By making the 2nd battery of lens G42Move along optical axis from the lateral object side of imaging surface IMG and make the 3rd
Battery of lens G43Along optical axis from object lateral imaging surface IMG side shifting, thus carry out along with zoom
The correction of the position of the imaging surface IMG caused.Now, opening diaphragm STP and the 2nd battery of lens G42
Move together.Further, by making the 1st battery of lens G41Move along optical axis direction object side, thus enter
Row is from the focusing of infinity object focus state to minimum distance object focus state.
Below, it is shown that the various numeric datas relevant to the zoom lens of embodiment 4.
Focal length=3.09 (wide-angle side) of zoom lens whole system~25.28 (telescope ends)
F value (FNO)=1.24 (wide-angle side)~5.59 (telescope ends)
Angle of half field-of view (ω)=51.14 (wide-angle side)~6.52 (telescope ends)
1st battery of lens G41Focal length (f1)=-8.88
2nd battery of lens G42Focal length (f2)=13.73
3rd battery of lens G43Focal length (f3)=19.12
Zoom ratio=8.19
(lens data)
r1=46.713
d1=0.50 nd1=1.88 vd1=40.81
r2=9.500
d2=3.66
r3=21.676
d3=0.50 nd2=1.74 vd2=49.22
r4=10.262
d4=1.91
r5=27.990 (aspheric surfaces)
d5=4.13 nd3=1.82 vd3=24.06
r6=-23.453
d6=0.61
r7=-16.902
d7=0.50 nd4=1.62 vd4=63.86
r8=34.085 (aspheric surfaces)
d8=D (8) (variable)
r9=10.227 (aspheric surfaces)
d9=4.75 nd5=1.50 vd5=81.56
r10=-22.296 (aspheric surfaces)
d10=0.71
r11=∞ (opening diaphragm)
d11=1.57
r12=14.438
d12=0.60 nd6=1.90 vd6=31.01
r13=7.228
d13=4.59 nd7=1.44 vd7=95.10
r14=-43.169
d14=D (14) (variable)
r15=-11.021
d15=0.50 nd8=1.70 vd8=41.15
r16=10.104
d16=0.72
r17=16.174
d17=1.87 nd9=1.88 vd9=40.81
r18=-21.359
d18=0.50
r19=52.774 (aspheric surfaces)
d19=2.62 nd10=1.50 vd10=81.56
r20=-9.309 (aspheric surfaces)
d20=D (20) (variable)
r21=∞
d21=1.50 nd11=1.52 vd11=64.20
r22=∞
d22=4.00
r23=∞ (imaging surface)
Circular cone coefficient (k) and asphericity coefficient (A, B, C, D, E)
(the 5th face)
K=0,
A=0,
B=-4.22974 × 10-6, C=3.00580 × 10-6,
D=-3.72775 × 10-8, E=5.19830 × 10-10
(the 8th face)
K=0,
A=0,
B=-1.96237 × 10-4, C=1.99541 × 10-6,
D=-1.40593 × 10-8, E=3.63024 × 10-11
(the 9th face)
K=0,
A=0,
B=-1.22444 × 10-4, C=-1.45093 × 10-6,
D=3,34444 × 10-8, E=-5.05995 × 10-10
(the 10th face)
K=0,
A=0,
B=9.71687 × 10-5, C=-1.08483 × 10-6,
D=2.66175 × 10-8, E=-3.52297 × 10-10
(the 19th face)
K=0,
A=0,
B=3.62043 × 10-4, C=2.31518 × 10-5,
D=2.37504 × 10-7, E=3.55302 × 10-8
(the 20th face)
K=0,
A=0,
B=5.38706 × 10-4, C=6.98508 × 10-5,
D=-4.18158 × 10-6, E=1.96092 × 10-7
(zoom data)
(numerical value relevant to conditional (1))
| β 2T/ β 2W |=7.71
β the 2T: the 2 battery of lens G42The multiplying power of telescope end
β the 2W: the 2 battery of lens G42The multiplying power of wide-angle side
(numerical value relevant to conditional (2))
β 2W=-0.39
(numerical value relevant to conditional (3))
β 2T=-3.03
(numerical value relevant to conditional (4))
3LT=0.94
β LT: at battery of lens (the 3rd battery of lens G that image side is configured43) the multiplying power of telescope end
(numerical value relevant to conditional (5))
| f1 |/f2=0.65
(numerical value relevant to conditional (6))
| f2/f3 |=0.72
(numerical value relevant to conditional (7))
Vd1p=24.06
Vd1p: the 1 battery of lens G41Included in plus lens (plus lens L413) to d line
Abbe number
(numerical value relevant to conditional (8))
Vd1n=63.86
Vd1n: the 1 battery of lens G41Included in minus lens (minus lens L414) to d line
Abbe number
(numerical value relevant to conditional (9))
Vd2pa=88.33
Vd2pa: the 2 battery of lens G42Included in the meansigma methods of the Abbe number to d line of plus lens
(numerical value relevant to conditional (10))
(R31+R32)/(R31-R32)=0.04
R31: the 3 battery of lens G43The minus lens L configured in most object side431Object side
Radius of curvature
R32: the 3 battery of lens G43The minus lens L configured in most object side431Image side surface
Radius of curvature
(numerical value relevant to conditional (11))
|X2|2/ (| f1 | × f2)=10.88
X2: from wide-angle side to telescope end carry out zoom time the 2nd battery of lens G42Amount of movement (=
36.43)
(numerical value relevant to conditional (12))
F2/fLw=0.72
FLw: the 3 battery of lens G43The synthesis in wide-angle side of all of battery of lens configured afterwards
Focal length
Fig. 8 is all aberration diagrams of the zoom lens of embodiment 4.In spherical aberration diagram, the longitudinal axis represents
F value (in figure, represents with FNO), and solid line represents the wavelength being equivalent to d line (λ=587.56nm)
Characteristic, short dash line represents the characteristic of the wavelength being equivalent to g line (λ=435.84nm), long dotted line
Represent the characteristic of the wavelength being equivalent to IR line (λ=850.00nm).In astigmatism figure, the longitudinal axis represents
Angle of half field-of view (in figure, represents with ω), represents the characteristic of the wavelength being equivalent to d line.Need explanation
, in astigmatism figure, solid line represents the characteristic of sagittal plane (in figure, representing), dotted line with S
Represent the characteristic of meridional plane (in figure, representing) with M.In distortion aberration diagram, the longitudinal axis represents
Angle of half field-of view (in figure, represents with ω), represents the characteristic of the wavelength being equivalent to d line.
[embodiment 5]
Fig. 9 is the sectional view along optical axis of the structure of the zoom lens representing embodiment 5.This zoom
Lens are configured to, and are configured with the 1st battery of lens with negative power from not shown object side successively
G51, there is the 2nd battery of lens G of positive light coke52, there is the 3rd battery of lens G of positive light coke53。
It addition, at the 3rd battery of lens G53And it is configured with protection glass between imaging surface IMG.
1st battery of lens G51It is configured to, from object side, is configured with minus lens L successively511, minus lens
L512, plus lens L513, minus lens L514.At plus lens L513Object side be formed with aspheric surface.
It addition, at minus lens L514Imaging surface IMG side be also formed with aspheric surface.
2nd battery of lens G52It is configured to, from object side, is configured with plus lens L successively521, for really
Establish rules opening diaphragm STP, the minus lens L of fixed bore522, plus lens L523.At plus lens L521
Two sides be formed with aspheric surface.Minus lens L522With plus lens L523Engage.
3rd battery of lens G53It is configured to, from object side, is configured with minus lens L successively531, plus lens
L532, plus lens L533.Minus lens L531Object side be concave surface.At plus lens L533Two sides
It is formed with aspheric surface.
In these zoom lens, by making the 1st battery of lens G51Along optical axis to be formed to imaging surface
The mode of the track that IMG side is protruded moves, thus carries out from wide-angle side to the zoom of telescope end.It addition,
By making the 2nd battery of lens G52Move along optical axis from the lateral object side of imaging surface IMG and make the 3rd
Battery of lens G53Move in the way of the track that object side protrudes gently to be formed along optical axis, thus enter
The correction of the position of the imaging surface IMG that row causes along with zoom.Now, opening diaphragm STP with
2nd battery of lens G52Move together.Further, by making the 1st battery of lens G51Along optical axis direction object
Side shifting, thus carry out gathering from infinity object focus state to minimum distance object focus state
Burnt.
Below, it is shown that the various numeric datas relevant to the zoom lens of embodiment 5.
Focal length=3.09 (wide-angle side) of zoom lens whole system~31.14 (telescope ends)
F value (FNO)=1.23 (wide-angle side)~6.50 (telescope ends)
Angle of half field-of view (ω)=55.16 (wide-angle side)~5.71 (telescope ends)
1st battery of lens G51Focal length (f1)=-9.90
2nd battery of lens G52Focal length (f2)=14.96
3rd battery of lens G53Focal length (f3)=19.46
Zoom ratio=10.09
(lens data)
r1=26.825
d1=0.50 nd1=1.88 vd1=40.81
r2=9.500
d2=6.87
r3=283.853
d3=0.50 nd2=1.64 vd2=55.45
r4=13.341
d4=1.24
r5=18.652 (aspheric surfaces)
d5=5.37 nd3=1.90 vd3=31.01
r6=-20.586
d6=0.32
r7=-18.586
d7=0.50 nd4=1.62 vd4=63.86
r8=14.772 (aspheric surfaces)
d8=D (8) (variable)
r9=10.932 (aspheric surfaces)
d9=4.89 nd5=1.50 vd5=81.56
r10=-22.740 (aspheric surfaces)
d10=0.71
r11=∞ (opening diaphragm)
d11=1.57
r12=15.124
d12=0.60 nd6=1.80 vd6=29.84
r13=7.157
d13=4.47 nd7=1.44 vd7=95.10
r14=415.217
d14=D (14) (variable)
r15=-9.835
d15=0.50 nd8=1.62 vd8=36.30
r16=11.290
d16=0.47
r17=14.063
d17=1.75 nd9=1.85 vd9=32.27
r18=-48.539
d18=0.50
r19=51.226 (aspheric surfaces)
d19=2.76 nd10=1.50 vd10=81.56
r20=-7.918 (aspheric surfaces)
d20=D (20) (variable)
r21=∞
d21=1.50 nd11=1.52 vd11=64.20
r22=∞
d22=4.00
r23=∞ (imaging surface)
Circular cone coefficient (k) and asphericity coefficient (A, B, C, D, E)
(the 5th face)
K=0,
A=0,
B=-1.08363 × 10-4, C=1.59004 × 10-6,
D=-1.70725 × 10-8, E=1.67325 × 10-10
(the 8th face)
K=0,
A=0,
B=-3.13596 × 10-4, C=2.52792 × 10-6,
D=-3.21565 × 10-8, E=2.34769 × 10-10
(the 9th face)
K=0,
A=0,
B=-1.02452 × 10-4, C=-5.67217 × 10-7,
D=6.25623 × 10-9, E=-1.12478 × 10-10
(the 10th face)
K=0,
A=0,
B=6.90491 × 10-5, C=-4.62562 × 10-7,
D=9.12845 × 10-9, E=-8.83652 × 10-11
(the 19th face)
K=0,
A=0,
B=3.19106 × 10-4, C=1.97993 × 10-5,
D=1.84618 × 10-7, E=3.07653 × 10-8
(the 20th face)
K=0,
A=0,
B=7.27355 × 10-4, C=5.37611 × 10-5,
D=-3.02061 × 10-6, E=1.47278 × 10—7
(zoom data)
(numerical value relevant to conditional (1))
| β 2T/ β 2W |=9.33
β the 2T: the 2 battery of lens G52The multiplying power of telescope end
β the 2W: the 2 battery of lens G52The multiplying power of wide-angle side
(numerical value relevant to conditional (2))
β 2W=-0.37
(numerical value relevant to conditional (3))
β 2T=-3.44
(numerical value relevant to conditional (4))
β LT=0.92
β LT: at battery of lens (the 3rd battery of lens G that image side is configured53) the multiplying power of telescope end
(numerical value relevant to conditional (5))
| f1 |/f2=0.66
(numerical value relevant to conditional (6))
| f2/f3 |=0.77
(numerical value relevant to conditional (7))
Vd1p=31.01
Vd1p: the 1 battery of lens G51Included in plus lens (plus lens L513) to d line
Abbe number
(numerical value relevant to conditional (8))
Vd1n=63.86
Vd1n: the 1 battery of lens G51Included in minus lens (minus lens L514) to d line
Abbe number
(numerical value relevant to conditional (9))
Vd2pa=88.33
Vd2pa: the 2 battery of lens G52Included in the meansigma methods of the Abbe number to d line of plus lens
(numerical value relevant to conditional (10))
(R31+R32)/(R31-R32)=-0.07
R31: the 3 battery of lens G53The minus lens L configured in most object side531Object side
Radius of curvature
R32: the 3 battery of lens G53The minus lens L configured in most object side531Image side surface
Radius of curvature
(numerical value relevant to conditional (11))
|X2|2/ (| f1 | × f2)=14.46
X2: from wide-angle side to telescope end carry out zoom time the 2nd battery of lens G52Amount of movement (=
46.27)
(numerical value relevant to conditional (12))
F2/fLw=0.77
FLw: the 3 battery of lens G53The synthesis in wide-angle side of all of battery of lens configured afterwards
Focal length
Figure 10 is all aberration diagrams of the zoom lens of embodiment 5.In spherical aberration diagram, longitudinal axis table
Showing F value (in figure, representing) with FNO, solid line represents and is equivalent to d line (λ=587.56nm)
The characteristic of wavelength, short dash line represents the characteristic of the wavelength being equivalent to g line (λ=435.84nm), long
Dotted line represents the characteristic of the wavelength being equivalent to IR line (λ=850.00nm).In astigmatism figure, the longitudinal axis
Represent angle of half field-of view (in figure, representing with ω), represent the characteristic of the wavelength being equivalent to d line.Need
Illustrating, in astigmatism figure, solid line represents the characteristic of sagittal plane (in figure, representing) with S,
Dotted line represents the characteristic of meridional plane (in figure, representing) with M.In distortion aberration diagram, the longitudinal axis
Represent angle of half field-of view (in figure, representing with ω), represent the characteristic of the wavelength being equivalent to d line.
[embodiment 6]
Figure 11 is the sectional view along optical axis of the structure of the zoom lens representing embodiment 6.This change
Focus lens is configured to, and is configured with the 1st lens with negative power from not shown object side successively
Group G61, there is the 2nd battery of lens G of positive light coke62, there is the 3rd battery of lens G of positive light coke63。
It addition, at the 3rd battery of lens G63And it is configured with protection glass between imaging surface IMG.
1st battery of lens G61It is configured to, from object side, is configured with minus lens L successively611, minus lens
L612, plus lens L613, minus lens L614.Minus lens L612With plus lens L613Engage.At plus lens
L613Imaging surface IMG side be formed with aspheric surface.
2nd battery of lens G62It is configured to, from object side, is configured with the bore for determining regulation successively
Opening diaphragm STP, plus lens L621, minus lens L622, plus lens L623.At plus lens L621
Two sides be formed with aspheric surface.Minus lens L622With plus lens L623Engage.
3rd battery of lens G63It is configured to, from object side, is configured with minus lens L successively631, plus lens
L632, plus lens L633.Minus lens L631Object side be concave surface.At plus lens L633Two sides
It is formed with aspheric surface.
In these zoom lens, by making the 1st battery of lens G61Along optical axis to be formed to imaging surface
The mode of the track that IMG side is protruded moves, thus carries out from wide-angle side to the zoom of telescope end.It addition,
By making the 2nd battery of lens G62Move along optical axis from the lateral object side of imaging surface IMG and make the 3rd
Battery of lens G63Along optical axis from object lateral imaging surface IMG side shifting, thus carry out along with zoom
The correction of the position of the imaging surface IMG caused.Now, opening diaphragm STP and the 2nd battery of lens G62
Move together.Further, by making the 1st battery of lens G61Move along optical axis direction object side, thus enter
Row is from the focusing of infinity object focus state to minimum distance object focus state.
Below, it is shown that the various numeric datas relevant to the zoom lens of embodiment 6.
Focal length=3.19 (wide-angle side) of zoom lens whole system~19.44 (telescope ends)
F value (FNO)=1.23 (wide-angle side)~3.46 (telescope ends)
Angle of half field-of view (ω)=63.45 (wide-angle side)~9.03 (telescope ends)
1st battery of lens G61Focal length (f1)=-8.87
2nd battery of lens G62Focal length (f2)=14.15
3rd battery of lens G63Focal length (f3)=20.70
Zoom ratio=6.09
(lens data)
r1=-1214.004
d1=0.50 nd1=1.90 vd1=37.37
r2=9.500
d2=4.39
r3=-41.362
d3=0.50 nd2=1.62 vd2=60.34
r4=34.311
d4=3.06 nd3=1.92 vd3=20.88
r5=-38.697 (aspheric surfaces)
d5=0.82
r6=-16.500
d6=0.50 nd4=1.50 vd4=81.56
r7=-276.937
d7=D (7) (variable)
r8=∞ (opening diaphragm)
d8=0.10
r9=11.908 (aspheric surfaces)
d9=4.09 nd5=1.55 vd5=71.68
r10=-23.716 (aspheric surfaces)
d10=2.28
r11=31.163
d11=0.60 nd6=1.74 vd6=32.26
r12=8.502
d12=4.13 nd7=1.44 vd7=95.10
r13=-20.456
d13=D (13) (variable)
r14=-8.639
d14=0.50 nd8=1.52 vd8=52.15
r15=49.450
d15=0.53
r16=-56.822
d16=1.83 nd9=1.55 vd9=71.68
r17=-10.549
d17=0.50
r18=37.725 (aspheric surfaces)
d18=2.56 nd10=1.50 vd10=81.56
r19=-10.893 (aspheric surfaces)
d19=D (19) (variable)
r20=∞
d20=1.50 nd11=1.52 vd11=64.20
r21=∞
d21=4.00
r22=∞ (imaging surface)
Circular cone coefficient (k) and asphericity coefficient (A, B, C, D, E)
(the 5th face)
K=0,
A=0,
B=-6.43049 × 10-5, C=-3.13937 × 10-7,
D=7.90770 × 10-10, E=-2.56196×10-11
(the 9th face)
K=0,
A=0,
B=-9.58017 × 10-5, C=-5.28701 × 10-7,
D=2.20174 × 10-8, E=-3.25046 × 10-10
(the 10th face)
K=0,
A=0,
B=9.23714 × 10-5, C=-7.68271 × 10-7,
D=2.53988 × 10-8, E=-3.43261 × 10-10
(the 18th face)
K=0,
A=0,
B=2.09121 × 10-4, C=1.63339 × 10-5,
D=1.84981 × 10-8, E=2.83988 × 10-8
(the 19th face)
K=0,
A=0,
B=4.45201 × 10-4, C=3.75015 × 10-5,
D=-1.86997 × 10-6, E=9.73204 × 10-8
(zoom data)
(numerical value relevant to conditional (1))
| β 2T/ β 2W |=5.82
β the 2T: the 2 battery of lens G62The multiplying power of telescope end
β the 2W: the 2 battery of lens G62The multiplying power of wide-angle side
(numerical value relevant to conditional (2))
β 2W=-0.45
(numerical value relevant to conditional (3))
β 2T=-2.60
(numerical value relevant to conditional (4))
β LT=0.84
β LT: at battery of lens (the 3rd battery of lens G that image side is configured63) the multiplying power of telescope end
(numerical value relevant to conditional (5))
| f1 |/f2=0.63
(numerical value relevant to conditional (6))
| f2/f3 |=0.68
(numerical value relevant to conditional (7))
Vd1p=20.88
Vd1p: the 1 battery of lens G61Included in plus lens (plus lens L613) to d line
Abbe number
(numerical value relevant to conditional (8))
Vd1n=81.56
Vd1n: the 1 battery of lens G61Included in minus lens (minus lens L614) to d line
Abbe number
(numerical value relevant to conditional (9))
Vd2pa=83.39
Vd2pa: the 2 battery of lens G62Included in the meansigma methods of the Abbe number to d line of plus lens
(numerical value relevant to conditional (10))
(R31+R32)/(R31-R32)=-0.70
R31: the 3 battery of lens G63The minus lens L configured in most object side631Object side
Radius of curvature
R32: the 3 battery of lens G63The minus lens L configured in most object side631Image side surface
Radius of curvature
(numerical value relevant to conditional (11))
|X2|2/ (| f1 | × f2)=7.55
X2: from wide-angle side to telescope end carry out zoom time the 2nd battery of lens G62Amount of movement (=
30.78)
(numerical value relevant to conditional (12))
F2/fLw=0.68
FLw: the 3 battery of lens G63The synthesis in wide-angle side of all of battery of lens configured afterwards
Focal length
Figure 12 is all aberration diagrams of the zoom lens of embodiment 6.In spherical aberration diagram, longitudinal axis table
Showing F value (in figure, representing) with FNO, solid line represents and is equivalent to d line (λ=587.56nm)
The characteristic of wavelength, short dash line represents the characteristic of the wavelength being equivalent to g line (λ=435.84nm), long
Dotted line represents the characteristic of the wavelength being equivalent to IR line (λ=850.00nm).In astigmatism figure, the longitudinal axis
Represent angle of half field-of view (in figure, representing with ω), represent the characteristic of the wavelength being equivalent to d line.Need
Illustrating, in astigmatism figure, solid line represents the characteristic of sagittal plane (in figure, representing) with S,
Dotted line represents the characteristic of meridional plane (in figure, representing) with M.In distortion aberration diagram, the longitudinal axis
Represent angle of half field-of view (in figure, representing with ω), represent the characteristic of the wavelength being equivalent to d line.
[embodiment 7]
Figure 13 is the sectional view along optical axis of the structure of the zoom lens representing embodiment 7.This change
Focus lens is configured to, and is configured with the 1st lens with negative power from not shown object side successively
Group G71, there is the 2nd battery of lens G of positive light coke72, there is the 3rd battery of lens G of negative power73、
There is the 4th battery of lens G of positive light coke74.It addition, at the 4th battery of lens G74With imaging surface IMG
Between be configured with protection glass.
1st battery of lens G71It is configured to, from object side, is configured with minus lens L successively711, minus lens
L712, plus lens L713, minus lens L714.At plus lens L713Object side be formed with aspheric surface.
It addition, at minus lens L714Imaging surface IMG side be also formed with aspheric surface.
2nd battery of lens G72It is configured to, from object side, is configured with plus lens L successively721, for really
Establish rules opening diaphragm STP, the minus lens L of fixed bore722, plus lens L723.At plus lens L721
Two sides be formed with aspheric surface.Minus lens L722With plus lens L723Engage.
3rd battery of lens G73It is configured to, from object side, is configured with minus lens L successively731, plus lens
L732.Minus lens L731Object side be concave surface.
4th battery of lens G74By plus lens L741Constitute.At plus lens L741Two sides be formed with aspheric
Face.
In these zoom lens, by making the 1st battery of lens G71Along optical axis to be formed to imaging surface
The mode of the track that IMG side is protruded moves, thus carries out from wide-angle side to the zoom of telescope end.It addition,
By making the 2nd battery of lens G72Move along optical axis from the lateral object side of imaging surface IMG and make the 3rd
Battery of lens G73Move in the way of the track that imaging surface IMG side is protruded gently along optical axis to be formed,
And make the 4th battery of lens G74Along optical axis from object lateral imaging surface IMG side shifting, thus carry out
The correction of the position of the imaging surface IMG caused along with zoom.Now, opening diaphragm STP and
2 battery of lens G72Move together.Further, by making the 1st battery of lens G71Along optical axis direction object sidesway
Dynamic, thus carry out the focusing from infinity object focus state to minimum distance object focus state.
Below, it is shown that the various numeric datas relevant to the zoom lens of embodiment 7.
Focal length=3.09 (wide-angle side) of zoom lens whole system~31.12 (telescope ends)
F value (FNO)=1.23 (wide-angle side)~6.88 (telescope ends)
Angle of half field-of view (ω)=52.03 (wide-angle side)~5.41 (telescope ends)
1st battery of lens G71Focal length (f1)=-9.07
2nd battery of lens G72Focal length (f2)=14.59
3rd battery of lens G73Focal length (f3)=-34.24
4th battery of lens G74Focal length=17.08
Zoom ratio=10.08
(lens data)
r1=20.859
d1=0.50 nd1=1.88 vd1=40.81
r2=9.500
d2=7.87
r3=-73.957
d3=0.50 nd2=1.64 vd2=55.45
r4=12.285
d4=1.44
r5=18.848 (aspheric surfaces)
d5=5.30 nd3=1.90 vd3=31.01
r6=-20.815
d6=0.41
r7=-17.927
d7=0.50 nd4=1.62 vd4=63.86
r8=15.963 (aspheric surfaces)
d8=D (8) (variable)
r9=11.414 (aspheric surfaces)
d9=5.08 nd5=1.50 vd5=81.56
r10=-23.827 (aspheric surfaces)
d10=0.71
r11=∞ (opening diaphragm)
d11=1.57
r12=16.271
d12=0.83 nd6=1.80 vd6=29.84
r13=7.720
d13=4.82 nd7=1.44 vd7=95.10
r14=-54.939
d14=D (14) (variable)
r15=-12.976
d15=0.50 nd8=1.62 vd8=36.30
r16=12.988
d16=1.13
r17=19.171
d17=1.59 nd9=1.85 vd9=32.27
r18=-57.591
d18=D (18) (variable)
r19=41.241 (aspheric surfaces)
d19=2.53 nd10=1.50 vd10=81.56
r20=-10.474 (aspheric surfaces)
d20=D (20) (variable)
r21=∞
d21=1.50 nd11=1.52 vd11=64.20
r22=∞
d22=4.00
r23=∞ (imaging surface)
Circular cone coefficient (k) and asphericity coefficient (A, B, C, D, E)
(the 5th face)
K=0,
A=0,
B=-1.10804 × 10-4, C=2.40067 × 10-6,
D=-2.80248 × 10-8, E=2.34615 × 10-10
(the 8th face)
K=0,
A=0,
B=-3.03764 × 10-4, C=3.42411 × 10-6,
D=-4.75443 × 10-8, E=3.55623 × 10-10
(the 9th face)
K=0,
A=0,
B=-9.31203 × 10-5, C=-4.35845 × 10-7,
D=3.02696 × 10-9, E=-5.65335 × 10-11
(the 10th face)
K=0,
A=0,
B=7.16629 × 10-5, C=-5.08309 × 10-7,
D=7.05728 × 10-9, E=-5.04859 × 10-11
(the 19th face)
K=0,
A=0,
B=3.31171 × 10-4, C=2.53313 × 10-5,
D=7.07224 × 10-8, E=2.98452 × 10-8
(the 20th face)
K=0,
A=0,
B=5.29799 × 10-4, C=6.53044 × 10-5,
D=-3.34111 × 10-6, E=1.60775 × 10-7
(zoom data)
(numerical value relevant to conditional (1))
| β 2T/ β 2W |=8.18
β the 2T: the 2 battery of lens G72The multiplying power of telescope end
β the 2W: the 2 battery of lens G72The multiplying power of wide-angle side
(numerical value relevant to conditional (2))
β 2W=-0.37
(numerical value relevant to conditional (3))
β 2T=-2.98
(numerical value relevant to conditional (4))
β LT=0.66
β LT: at battery of lens (the 4th battery of lens G that image side is configured74) the multiplying power of telescope end
(numerical value relevant to conditional (5))
| f1 |/f2=0.62
(numerical value relevant to conditional (6))
| f2/f3 |=0.43
(numerical value relevant to conditional (7))
Vd1p=31.01
Vd1p: the 1 battery of lens G71Included in plus lens (plus lens L713) to d line
Abbe number
(numerical value relevant to conditional (8))
Vd1n=63.86
Vd1n: the 1 battery of lens G71Included in minus lens (minus lens L714) to d line
Abbe number
(numerical value relevant to conditional (9))
Vd2pa=88.33
Vd2pa: the 2 battery of lens G72Included in the meansigma methods of the Abbe number to d line of plus lens
(numerical value relevant to conditional (10))
(R31+R32)/(R31-R32)=0.00
R31: the 3 battery of lens G73The minus lens L configured in most object side731Object side
Radius of curvature
R32: the 3 battery of lens G73The minus lens L configured in most object side731Image side surface
Radius of curvature
(numerical value relevant to conditional (11))
|X2|2/ (| f1 | × f2)=14.68
X2: from wide-angle side to telescope end carry out zoom time the 2nd battery of lens G72Amount of movement (=
44.07)
(numerical value relevant to conditional (12))
F2/fLw=0.62
FLw: the 3 battery of lens G73The synthesis in wide-angle side of all of battery of lens configured afterwards
Focal length (=23.70)
Figure 14 is all aberration diagrams of the zoom lens of embodiment 7.In spherical aberration diagram, longitudinal axis table
Showing F value (in figure, representing) with FNO, solid line represents and is equivalent to d line (λ=587.56nm)
The characteristic of wavelength, short dash line represents the characteristic of the wavelength being equivalent to g line (λ=435.84nm), long
Dotted line represents the characteristic of the wavelength being equivalent to IR line (λ=850.00nm).In astigmatism figure, the longitudinal axis
Represent angle of half field-of view (in figure, representing with ω), represent the characteristic of the wavelength being equivalent to d line.Need
Illustrating, in astigmatism figure, solid line represents the characteristic of sagittal plane (in figure, representing) with S,
Dotted line represents the characteristic of meridional plane (in figure, representing) with M.In distortion aberration diagram, the longitudinal axis
Represent angle of half field-of view (in figure, representing with ω), represent the characteristic of the wavelength being equivalent to d line.
It should be noted that in numeric data in the various embodiments described above, r1、r2, table
Show the radius of curvature in each lens, diaphragm face etc., d1、d2, represent each lens, diaphragm etc.
Wall thickness or interval, their face, nd1、nd2, represent each lens etc. to d line (λ=
Refractive index 587.56nm), vd1、vd2, represent each lens etc. to d line (λ=587.56nm)
Abbe number.Further, the unit of length is " mm ", and the unit of angle is " ° ".
It addition, for above-mentioned each aspherical shape, the height on the direction vertical with optical axis is set to
H, will be set to X, nearly with lens face top for the displacement at optical axis direction of height H during initial point
Paraxial curvature radius is set to R, and circular cone coefficient is set to k, by 2 times, 4 times, 6 times, 8 times, 10 times
Asphericity coefficient be set to A, B, C, D, E, the direct of travel of light is set to timing, logical
Cross formula shown below to represent.
[formula 1]
As shown in the various embodiments described above, in accordance with the invention it is possible to realize small-sized, heavy caliber and can
The powerful of high optical property is possessed what all aberrations were maked corrections by whole zoom region well
Zoom lens.Particularly, by meeting conditional (7), (8), (9), it is possible to realize not only can
See that the zoom possessing high optical property of the shooting that the whole region of light can also carry out near-infrared area of light is saturating
Mirror.Further, these zoom lens have been suitably formed aspheric lens, cemented lens by configuring, from
And optical property can be improved further.
Industrial utilizability
As it has been described above, the zoom lens of the present invention are for being equipped with the solid-state image pickups such as CCD, CMOS
The small-sized camera head of element is useful, is especially suitable for requiring the camera head of high optical property.
Claims (15)
1. zoom lens, it possess configure successively from object side there is the 1st of negative power
Battery of lens, there is the 2nd battery of lens of positive light coke, the 3rd battery of lens, and by each battery of lens
The change at the interval on optical axis carries out zoom, and described zoom lens are characterised by,
Plus lens that described 2nd battery of lens includes configuring successively from object side, minus lens, plus lens,
Described 3rd battery of lens is constituted according to the mode being configured with minus lens in most object side,
And meet conditional shown below,
(1)2.8≤|β2T/β2W|≤12.0
Wherein, β 2T represents the multiplying power of the telescope end of described 2nd battery of lens, and β 2W represents the described 2nd
The multiplying power of the wide-angle side of battery of lens.
Zoom lens the most according to claim 1, it is characterised in that
Zoom is carried out by making described 1st battery of lens move along optical axis,
Moved along optical axis by the battery of lens after making described 2nd battery of lens, draw along with zoom
The image planes variation risen makes corrections,
By making described 1st battery of lens move along optical axis direction object side, carry out closing from infinity object
Coke-like state is to the focusing of minimum distance object focus state.
Zoom lens the most according to claim 1 and 2, it is characterised in that
Also meet conditional shown below,
(2)-0.5≤β2W≤-0.1
Wherein, β 2W represents the multiplying power of wide-angle side of described 2nd battery of lens.
Zoom lens the most according to any one of claim 1 to 3, it is characterised in that
Also meet conditional shown below,
(3)-4.50≤β2T≤-1.45
Wherein, β 2T represents the multiplying power of telescope end of described 2nd battery of lens.
Zoom lens the most according to any one of claim 1 to 4, it is characterised in that
Also meet conditional shown below,
(4)0.3≤βLT≤1.0
Wherein, β LT represents the multiplying power at the telescope end of the battery of lens that image side is configured.
Zoom lens the most according to any one of claim 1 to 5, it is characterised in that
The opening diaphragm of opening for determining regulation is possessed in described 2nd battery of lens,
When from wide-angle side to the zoom of telescope end, described opening diaphragm is together with described 2nd battery of lens
Move to object side from image side.
Zoom lens the most according to any one of claim 1 to 6, it is characterised in that
Also meet conditional shown below,
(5)0.35≤|f1|/f2≤0.85
Wherein, f1 represents the focal length of described 1st battery of lens, and f2 represents the focal length of described 2nd battery of lens.
Zoom lens the most according to any one of claim 1 to 7, it is characterised in that
Also meet conditional shown below,
(6)0.2≤|f2/f3|≤1.0
Wherein, f2 represents the focal length of described 2nd battery of lens, and f3 represents the focal length of described 3rd battery of lens.
Zoom lens the most according to any one of claim 1 to 8, it is characterised in that
Described 1st battery of lens is constituted according to the mode at least including one piece of plus lens and one piece of minus lens,
And meet conditional shown below,
(7)vd1p≤41.0
(8)vd1n≥50.0
Wherein, vd1p represents the Abbe number to d line of the plus lens included in described 1st battery of lens,
Vd1n represents the Abbe number to d line of the minus lens included in described 1st battery of lens.
Zoom lens the most according to any one of claim 1 to 9, it is characterised in that
Also meet conditional shown below,
(9)vd2pa≥68.0
Wherein, vd2pa represents the Abbe to d line of the plus lens included in described 2nd battery of lens
The meansigma methods of number.
11. zoom lens according to any one of claim 1 to 10, it is characterised in that
Described 1st battery of lens is configured to, be configured with the most continuously from object side minus lens, minus lens,
Plus lens.
12. according to the zoom lens according to any one of claim 1 to 11, it is characterised in that
Described 3rd battery of lens is configured to, and is configured with minus lens, plus lens from object side the most continuously.
13. according to the zoom lens according to any one of claim 1 to 12, it is characterised in that
The minus lens configured in most object side of described 3rd battery of lens make concave surface towards object side,
And meet conditional shown below,
(10)-1.5≤(R31+R32)/(R31-R32)≤0.3
Wherein, R31 represents the object of the minus lens configured in most object side of described 3rd battery of lens
The radius of curvature of side, R32 represents the minus lens configured in most object side of described 3rd battery of lens
The radius of curvature of image side surface.
14. according to the zoom lens according to any one of claim 1 to 13, it is characterised in that
Also meet conditional shown below,
(11)4.5≤|X2|2/(|f1|×f2)≤16.5
Wherein, X2 represents the movement from wide-angle side to described 2nd battery of lens during zoom of telescope end
Amount, f1 represents the focal length of described 1st battery of lens, and f2 represents the focal length of described 2nd battery of lens.
15. according to the zoom lens according to any one of claim 1 to 14, it is characterised in that
Also meet conditional shown below,
(12)0.3≤f2/fLw≤1.1
Wherein, f2 represents the focal length of described 2nd battery of lens, after fLw represents described 3rd battery of lens
The synthesis focal length in wide-angle side of all of battery of lens configured.
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CN111352223A (en) * | 2018-12-21 | 2020-06-30 | 株式会社腾龙 | Wide-angle zoom lens and imaging device |
CN111522131A (en) * | 2019-02-01 | 2020-08-11 | 扬明光学股份有限公司 | Fixed focus lens and manufacturing method thereof |
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JP6555935B2 (en) * | 2015-06-05 | 2019-08-07 | キヤノン株式会社 | Zoom lens and imaging apparatus having the same |
JP7254271B2 (en) * | 2019-01-28 | 2023-04-10 | 株式会社ニコン | Variable magnification optical system, optical equipment |
JP7443046B2 (en) | 2019-03-29 | 2024-03-05 | キヤノン株式会社 | Zoom lens and imaging device with it |
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JP5939788B2 (en) * | 2011-12-21 | 2016-06-22 | キヤノン株式会社 | Zoom lens and imaging apparatus having the same |
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2014
- 2014-12-26 JP JP2014265327A patent/JP6367707B2/en not_active Expired - Fee Related
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2015
- 2015-08-11 CN CN201510489710.XA patent/CN106199936B/en active Active
- 2015-08-20 US US14/830,903 patent/US20160187629A1/en not_active Abandoned
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CN102549472A (en) * | 2010-05-19 | 2012-07-04 | 柯尼卡美能达精密光学株式会社 | Zoom lens and imaging device |
US20140049672A1 (en) * | 2012-08-17 | 2014-02-20 | Canon Kabushiki Kaisha | Zoom lens and image pickup apparatus including the same |
US20140300781A1 (en) * | 2013-04-03 | 2014-10-09 | Canon Kabushiki Kaisha | Zoom lens and image pickup apparatus including the same |
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CN111352223A (en) * | 2018-12-21 | 2020-06-30 | 株式会社腾龙 | Wide-angle zoom lens and imaging device |
CN111522131A (en) * | 2019-02-01 | 2020-08-11 | 扬明光学股份有限公司 | Fixed focus lens and manufacturing method thereof |
Also Published As
Publication number | Publication date |
---|---|
JP2016126085A (en) | 2016-07-11 |
CN106199936B (en) | 2018-12-18 |
JP6367707B2 (en) | 2018-08-01 |
US20160187629A1 (en) | 2016-06-30 |
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